ZIKV Epidemiology
Geographical distribution of the ZIKV
The virus was first isolated in April 1947 in a sentinel rhesus monkey (Rhesus 766) caged in the canopy of the lush Zika (meaning “overgrown” in the local Luganda language) forest of Uganda, by the side of Lake Victoria, during a study of yellow fever immunity of monkeys in the Entebbe peninsula; the virus was subsequently identified and named as the ZIKV.1 The virus was also found in the A. africanus mosquitoes in the following year, indicating a sylvatic cycle of infection and transmission through the arthropods.
Human infection was suspected from a serosurvey of residents of areas nearby the Zika region in 1951, which revealed presence of ZIKV antibodies.5 While the first identified Zika infection was commonly believed to be in Nigeria in 1954, recent reports indicate that the first laboratory confirmed cases of Zika infection in humans were in Uganda, Tanzania and India in 1952, then in 1953 in Nigeria, Malaya, Borneo and the Philippines, and in more countries in Equatorial Africa and Asia in subsequent years.3
A concise summary of all Zika viral infections and detections in the years prior to the first epidemic is given in Table 1 and a world map of these areas is presented in Figure 1. In all these cases, the infected persons reported mild fevers, headaches and body pains, symptoms often confused with DENV and chikungunya, two other viral diseases that are often endemic in the same areas and are transmitted by the same vectors. Indeed, this may have caused many Zika infections to be mistaken as DENV or chikungunya. Moreover, such symptoms led Zika viral disease to be considered as benign all through the 20th century.
Table 1Zika virus detected from 1947, the pre-epidemic period
Year | Country | Remarks |
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1947 | Uganda | First isolation and identification of ZIKV. Found in rhesus monkey, R766, caged in Zika forest. |
1948 | Uganda | Detected in A. africanus mosquitoes. Found in Zika forest. |
1951 | Nigeria | First instance of ZIKV antibodies in human blood, found in children. |
1952 | Uganda, Tanganyika | First human cases of ZIKV infection detected. |
| India | ZIKV antibodies found in human blood. |
1953 | Malaya, North Borneo, Philippines | ZIKV antibodies found in residents. |
| Nigeria | ZIKV infection detected in three persons. |
1954 | Egypt, Vietnam | ZIKV antibodies found in few residents. |
1955 | Nigeria | ZIKV antibodies found in human blood. |
1957 | Mozambique | ZIKV antibodies found in human blood. |
1958 | Uganda | Two strains of ZIKV found in A. aegypti mosquitoes in Zika forest. |
1960 | Angola | ZIKV antibodies found in indigenous residents. |
1961–62 | Central African Republic | ZIKV antibodies found in human blood. |
1961–64 | Ethiopia | ZIKV antibodies found in human blood. |
1962 | Senegal | ZIKV antibodies found in human blood. |
1963–64 | Central African Republic, Burkina-Faso | ZIKV antibodies found in human blood. |
1963–65 | Ivory Coast | ZIKV antibodies found in human blood. |
1964 | Uganda | First confirmation that ZIKV causes human disease. Clinical features reported. |
1964–65 | Guinea-Bissau | ZIKV antibodies found in human blood. |
1964–66 | Togo, Cameroon | ZIKV antibodies found in human blood. |
1965 | Niger | ZIKV antibodies found in human blood. |
1965–67 | Nigeria | ZIKV antibodies found in human blood. |
1967 | Benin, Gabon, Liberia | ZIKV antibodies found in human blood. |
1966–67 | Uganda, Kenya, Somalia, Morocco | ZIKV antibodies found in human blood. |
1967–69 | Uganda | ZIKV antibodies found in human blood. |
1968 | Kenya | ZIKV antibodies found in human blood. |
1969–72 | Nigeria | ZIKV antibodies found in human blood. |
1969 | Malaysia | ZIKV found in A. aegypti mosquitoes. |
1969–83 | Indonesia, Malaysia, Pakistan | ZIKV found in mosquitoes. Sporadic human infections. |
1970 | Nigeria | ZIKV antibodies found in human blood. |
1971–72 | Angola | ZIKV antibodies found in human blood. |
1972,1975, 1988,1990 | Senegal | ZIKV antibodies found in human blood. |
1979 | Central African Republic | ZIKV antibodies found in human blood. |
1980 | Nigeria | ZIKV antibodies found in human blood. |
1984 | Uganda | ZIKV antibodies found in human blood. |
1996–97 | Malaysia | ZIKV antibodies found in human blood. |
1999 | Ivory Coast | ZIKV antibodies found in human blood. |
The first reported outbreak of the ZIKV was from Yap Island in the Federated States of Micronesia in 2007, where about 5,000 of the 6,700 residents were infected. The next outbreak was reported from French Polynesia, affecting around 32,000 people, where instances of Guillain-Barre syndrome (GBS), a disease that causes muscle weakness from damage to the peripheral nervous system, were also indicated. Further outbreaks occurred in the Pacific at Easter Islands, New Caledonia and Cook Islands in 2014 and in Samoa in 2015, whereas only sporadic instances of Zika infections were reported from countries in Asia.5
The most massive outbreak occurred in early 2015 in Brazil, South America, where the ZIKV spread rapidly from the initial location around Bahia to the contiguous states,4 leading the local government to report about 1.3 million infections by December 2015 (see Ref. [3] for detailed descriptions). Neighboring Colombia reported Zika infections by early 2016, and by April 2017, 48 countries in the Americas had reported autochthonous vector-borne transmission of the ZIKV leading to tens of thousands of cases of Zika infections.6Table 2 provides a brief timeline of these outbreaks.
Table 2ZIKV epidemics, 2007 to present
Year | Country | Remarks |
---|
2007 | Yap Island, Micronesia | First outbreak reported in humans. |
2008 | Senegal | First reported case of traveler infected in Senegal returning to home country and passing infection through sexual contact. |
2010 | Cameroon | ZIKV antibodies found in human blood. |
2010–2015 | Cambodia, Indonesia, Malaysia, Philippines, Thailand, Maldives | Mosquito transmission of ZIKV in these countries to travelers who then carried the infection to their home countries. |
2011–2014 | French Polynesia | Second reported outbreak of ZIKV infections. Connection with microcephaly and neurological disorders established later. |
2013–2014 | Chile, Cook Islands, New Caledonia | ZIKV outbreak. |
2013 | Tahiti | ZIKV isolated from patient’s semen showing sexual transmissibility. |
2014 | Zambia | ZIKV antibodies found in human blood. |
2015 April/May | Brazil, Bahia state | National Reference Laboratory, Brazil confirmed, by PCR, ZIKV infections, for the first time in the Americas. |
2015 July | Brazil | Zika cases confirmed by laboratory tests in 12states. Neurological disorders associated with prior viral infections detected primarily in the Bahia region. |
2015 October | South America | Colombia, Republic of Cabo Verde report confirmed cases of ZIKV infections. Brazil reported unusual increase in the number of cases of neonatal microcephaly. |
2015 November | Central and South America | Brazil reported 141 suspected cases of microcephaly and declared a national public health emergency. Brazil reported detection of ZIKV in amniotic fluid of fetuses with confirmed microcephaly. Suriname, Panama, El Salvador, Guatemala and Paraguay confirmed cases of ZIKV infection. The Pan American Health Organization and WHO issued an epidemiological alert. |
2015 November | Mexico | Three cases of ZIKV infection confirmed by PCR. |
2015 November | French Polynesia | Retrospective analysis reveals unusually large number of central nervous system malformations in fetuses and infants in 2014–2015. |
2015 December | Central and South America | Honduras, French Guiana and Martinique reported confirmed cases of ZIKV infections. |
2015 December | Puerto Rico | First confirmed case of Zika infection reported. |
2016 | Maldives | Finnish national working in Maldivestested positive for Zika after return to Finland. |
2016 January | Americas | Guyana reported the first PCR-confirmed case of locally acquired Zika infection. Ecuador, Bolivia, Barbados, Haiti, Dominican Republic, Nicaragua, Curacao and Jamaica reported the first confirmed cases of Zika infections. First case of Zika in St. Martin reported. |
2016 January | US Virgin Islands | First confirmed case of Zika in St. Croix reported. |
2016 February | Americas | First confirmed case of ZIKV infection in Chile reported. First case of sexually transmitted Zika infection in Texas, USA reported. |
2016 | Various countries | Angola, Antigua, British Virgin Islands, Trinidad and Tobago, Guadulope, Fiji, Marshall Islands, Papua New Guinea, and other countries report first cases of ZIKV infections. |
2016 | Singapore | ZIKVinfection reported. |
2016/2017 | India | Three cases of ZIKV infection reported in Ahmedabad. |
2017 | Singapore | Several cases of locally transmitted ZIKVconfirmed. |
What was a shocking surprise was the several thousand neonatal microcephaly cases observed in the regions with ZIKV epidemic; subsequent analysis of the earlier French Polynesian outbreak showed a high level of neonatal microcephaly there also. This and other neurological disorders, such as GBS, were totally unexpected in scope and effect. Some Latin American countries advised their citizens to avoid pregnancies until the new virus was well understood7; the WHO responded by declaring a Public Health Emergency of International Concern (PHEIC) in February 2016, and relaxed it only in November of that same year.8
Cumulative data of cases of Zika viral infections and neurological disorders in the Americas following the epidemic are summarized region wise in Table 3. The scale of the incidence of microcephaly associated with ZIKV infections can be judged from the following data: the Centre for Disease Control and Prevention (CDC) of the U.S. Department of Health & Human Services (USA) estimated that microcephaly can occur at between 2 and 12 per 10,000 live births in the USA under normal circumstances9; and a study in India of neonatal microcephaly determined a rate of 2.3 per 10,000 births, similar to European estimates.10 The number of actual live births in the Americas between 2015 and May 2017 is not known, but the CDC estimated that among the 1,297 pregnancies reported in 2016 in the USA with suspected cases of ZIKV infection, laboratory confirmed cases of such infection showed a result that 1 in every 10 fetuses or infants with Zika-related development or birth defects, a considerably large number compared to normal circumstances.11
Table 3Cumulative cases of ZIKV infection in the Americas 2015–2017 as of 11 May 2017
Region* | Confirmed autochthonus cases | Imported cases | Deaths from ZIKVinfection | Confirmed congenital syndrome associated with ZIKV infection |
---|
North America | 225 | 5,478 | 0 | 67 |
Latin America (Mexico) | 8,731 | 15 | 0 | 5 |
Central American Isthmus | 6,309 | 77 | 0 | 81 |
Latin Caribbean | 41,823 | 205 | 5 | 143 |
Andean area | 15,136 | 41 | 0 | 167 |
Brazil | 133,527 | 0 | 11 | 2,653 |
Southern cone | 100 | 75 | 0 | 4 |
Non-Latin Caribbean | 5,649 | 29 | 4 | 10 |
TOTAL | 211,500 | 5,920 | 20 | 3,130 |
Transmission
From shortly after the discovery and identification of ZIKV, it was clear that transmission of the virus from animal to animal occurred through arthropods, of which A. africanus was the first to be identified (Table 1).1 The sylvatic cycle of transmission between non-human primates and mosquitoes prevalent in Africa was not observed in Asia, but subsequently a human-mosquito-human cycle of ZIKV infection came into being as the virus adapted to human hosts5. The primary arthropods identified in this cycle represented several subgroups of the Aedes mosquitoes. Two subspecies, A. aegypti and A. albopictus, have been found to be the main vectors of the disease of which the A. aegypti is the prime vector. It is relevant to note that the A, aegypti and other Aedes mosquitoes are also vectors for DENV and chikungunya viruses.
It is variously believed that the spread of ZIKV in recent years may have been caused by an infected traveler arriving at a new place, or perhaps an infected mosquito being inadvertently carried to the new place through various transports,12,13 possibilities that cannot be discounted in today’s world, where frequent travel and communications are commonplace. This may have happened before too, but the effect in Africa and Asia is believed to have been muted, due perhaps to immunities developed over many closely related viral and other diseases such as malaria, DENV and chikungunya. Such immunity may not have been indigent in Oceanian and American populations and, therefore, could have been the cause behind the large outbreaks there.3
Transmission of ZIKV can also be carried out by several other routes, including vertical transmission between mother and fetus through the placental barrier, sexual acts like vaginal, oral and anal sex, blood transfusions and organ transplants as well as laboratory exposure to the virus. Such exposures have led ZIKV RNA to be detected in urine, semen, female genital tract secretions, blood, saliva, breast milk, cerebrospinal fluid and amniotic fluid. These have been detected from between 1 week after onset of illness to about 6 months after, and human-to-human transmission is also suspected through body fluids, such as tears or sweat.14
Clinical manifestations
Onset of ZIKV illness takes place generally from 2 days to 2 weeks after being bitten by an infected mosquito in about 20–25% cases; the rest of the cases being asymptotic.14,15 The illness is usually mild, resolves in within a week, and provides immunity to further attacks.14 Symptoms typically include, inter alia, acute but low fever, body rash (especially in the face and trunk), headache, arthralgia and conjunctivitis, and less commonly including diarrhea, abdominal pain, etc. In children, intrauterine and intrapartum infections through vertical transmissions have been observed, but there have been no developmental problems reported in children who were infected after delivery.
As mentioned earlier, several of these symptoms are similar to those for DENV, chikungunya and many other diseases, leading to misinterpretation of many ZIKV cases as DENV or chikungunya, especially considering the years of experience of treating these diseases. The Pan American Health Organization, based on the experience gained from the French Polynesian outbreak, issued a provisional case definition (that ZIKV infection is to be suspected when a patient shows a low grade body temperature (>37.2 °C) and one or more of the following symptoms (not explained by other medical conditions): arthralgia or myalgia; non-purulent conjunctivitis or conjunctival hyperemia; headache or malaise.16 A confirmed case is a suspected case with a positive laboratory result, specifically for detection of ZIKV. Musso and Gubler further specified temperature range as 37.8–38.5 °C for Zika infection accompanied by pruritic rash (on face, trunk, extremities, soles),17 arthralgia and conjunctivitis (nonpurulent); indeed, conjunctivitis seems contra-indicated for DENV, chikungunya and other diseases with similar symptoms.14
The damaging effect of ZIKV became apparent only when Zika viral infections in pregnant mothers resulted in unusually high incidence of neonatal microcephaly and other neurological disorders (Table 3). The full range of anomalies in children born from women who had been infected with ZIKV during pregnancy is yet to be understood; a perspective on fetal ZIKV impact can be gleaned from the review by Cayne and Lazear.18 Severe cases of microcephaly have been seen to arrest intellectual development, slowdown physical development, affect locomotion, and, in some cases, lead to early death (see Ref. [17] for details of Zika clinical manifestations). The severity of the impact of this disease led several Latin American countries to advise precautionary steps for their citizens and other countries issued advisories against avoidable travel to countries where ZIKV infections have been noted (see e.g., Ref. [19]).20
A rare but notable neurological disorder, GBS has been reported from areas in Oceania and the Americas where there had been ZIKV outbreaks,5 with a short time lag.17 In French Polynesia, a study of patients with GBS and electrophysiological patterns compatible with acute motor axonal neuropathy detected anti-glycolipid antibody activities in the serum, particularly against the GA1 ganglioside.21 A study in Colombia evaluated 68 GBS patients in 2015–16 and found 97% had Zika infections within a month prior to the onset of the symptoms. Among those who could be tested with nerve-conduction studies, 78% suffered from the acute inflammatory demyelinating polyneuropathy subtype of GBS.22
ZIKV outbreaks and incidences of microcephaly in newborns in the Americas led the Pan American Health Organization and the WHO to declare several epidemiological alerts through 2015.16,23,24 By early 2016, the burden of circumstantial evidence of a link between ZIKV infection and congenital abnormalities and neurological disorders had become acute enough for the WHO to declare on 1 February 2016 the virus as a PHEIC. Later, on 18 November 2016, the WHO Emergency Committee concluded that the ZIKV and associated consequences constitute a significant and enduring public health challenge requiring intense action but no longer representing a PHEIC.8
By the end of 2016, the virus had spread north to 44 states of the USA and to all US Territories (Fig. 2), with reports of microcephaly, neurological disorders, eye abnormalities and other consequences of dysfunction of the central nervous system in newborns. Reportedly,15% of fetuses/infants born to women with confirmed ZIKV infection in the first trimester showed birth defects.11 The statistics up to 24 May 2017 showed that the US states including District of Columbia had 5,300 cases of ZIKV infections, and that there were 36,582 cases in US Territories, as reported to ArboNet.25 However, in South America the number of suspected and confirmed cases of ZIKV infection appear to be decreasing of late.6 On the other hand, three cases of ZIKV infection have been confirmed by laboratory tests in Ahmedabad, India in 2016 and recently reported26; the Government of India is taking steps to contain the spread of the virus.
Diagnosis
Diagnosis of ZIKV infection has been a difficult problem. As mentioned earlier, the symptoms bear close resemblance to DENV and chikungunya infections which are carried by the same vectors. Both latter infections, however, lead to high fever and body aches but are not associated with conjunctivitis, which is seen in case of Zika infections. There are similarities in symptoms with other viral diseases as well, from enterovirus and adenovirus to alphaviruses which also cause arthritis.
Diagnosis of the actual cause of infection has to be determined in qualified laboratories through serological tests or reverse transcription-polymerase chain reaction,14 which is time consuming. Efforts are being undertaken to develop equipment to make accurate diagnosis easier; for example, Sandia has developed a simple kit with smartphone app that the company claims will solve this issue while requiring very little training.27
Treating patients with Zika viral infection
There are no medicines for treating ZIKV patients. The standard procedure is to treat the symptoms.28 The patient is to be advised plenty of rest, liberal fluid intake to prevent dehydration, and some medicines, such as acetaminophen, to reduce fever. Aspirin, nimesulide and other anti-inflammatory drugs are to be avoided until DENV is ruled out by tests to avoid hemorrhage. For other medications, patients should consult their physicians.
For further precautionary measures, the patient should be kept in a mosquito-free environment to prevent spread of the disease. Those caring for the patient need to protect themselves from contamination through body fluids, bites by infected mosquitoes, or from handling infected clothing and other materials.
Prevention of infections from ZIKV
Since there are no prophylactics or therapeutics against the ZIKV, prevention of infection is the best recourse. The primary societal measure has to be control of the vectors that spread the disease, but this has proved to be extremely difficult. Brazil, for instance, had tried to eradicate the A. aegypti mosquitoes in their bid to arrest the spread of DENV in the pre-Zika period, but results have not been satisfactory.29 At the individual level the following steps are recommended (see also Ref. [30]):
Use mosquito nets and repellants to prevent mosquito bites. Wear long-sleeved clothing, as far as practical, for self and children. Use screens on windows and doors.
Avoid travel to areas known to have Zika viral infections, unless absolutely necessary. Check CDC and other travel advisories before undertaking a journey to Zika viral risk prone areas.
Keep yourself as secluded from contact with people as possible for several weeks if you have travelled to Zika prone areas.
Protect yourself and your partner during sexual contacts if either of you have risk of Zika infection.
Women need to be even more vigilant against the virus during pregnancies.31
Genetics of ZIKV
Although the ZIKV was isolated about 70 years ago and Bayesian evolutionary analysis estimates that the virus actually evolved between 1892 and 1943, it was little studied until very recently. The ZIKV is one species in the genus Flavivirus, family Flaviviridae, comprising a group of about 70 viruses, some of which are human-infecting, such as DENV, yellow fever virus, West Nile virus (WNV) and Japanese encephalitis virus (JEV). The most prominent mode of transmission of these viruses is by arthropod vectors such as ticks and mosquitoes, mainly of the Aedes species.
The ZIKV is also closely related to the Spondweni virus (SPONV), a flavivirus that is also transmitted by the Aedes species, with which the ZIKV has a nucleotide and amino acid identity covering a range of 68.3% to 69.0% and 74.6% to 75%, respectively, when compared with a group of nine ZIKV strains.32 The SPONV has been prevalent in Africa among cattle and other animals and only sporadically infecting humans, but its reservoir host is not known. The ZIKV, on the other hand, has adapted to human hosts and spread through Africa and Asia, causing the recent epidemics in Oceania and the New World. These events and other reports suggest that the SPONV and ZIKV are different species in the same Flavivirus family, but the low level of SPONV infection and spread compared to ZIKV with essentially the same vectors suggest they have low potential for SPONV transmissibility vis a vis ZIKV.32,33
The ZIKV genome
The human infecting arboviruses mentioned above are positive-sense, single-stranded, RNA viruses between 40 and 65 nm long, and enveloped with icosahedral-like structures containing linear, non-segmented genomes of around 10 to 11 kb in length encoding 10 proteins, including three structural proteins of capsid (C), pre-membrane/membrane (prM/M) and envelope (E) and seven non-structural (NS) proteins of NS1, NS2A, NS2B, NS3, NS4A, NS4B and NS5 (a “2K” 23 amino acid peptide is generated by cleavage of the N terminus of the NS4B signal sequence).34 Like the other flaviviruses, the ZIKV genome has flanking untranslated regions (UTRs) at the 5′- and the 3′-end with around 107 (5′-end) and 428 (3′-end) nucleotides, respectively. The genome structure is summarized in Table 4.34–41
Table 4Structure of a typical flavivirus genome including UTRs
Srl No | Gene | Sequence span,nt | Sequence length* | Protein/function | References |
---|
1 | 5′-UTR | 1–107 | 107 | Encodes regions essential for genome cyclization/replication. | [34] |
2 | Capsid | 108–473 | 366 | Virion structure. | [34] |
3 | prM/M | 474–977 | 504 | prM forms heterodimers with E to form immature virion. prM then cleaved and mature virions formed with M. | [34] |
4 | E | 978–2,489 | 1,512 | Viral entry into host cell. | [36] |
5 | NS1 | 2,490–3,545 | 1,056 | Viral replication, immune evasion, genome synthesis. | [37,38] |
6 | NS2A | 3,546–4,223 | 678 | Transmembrane protein, part of replication complex; assembly/secretion of virus particles. | [35] |
7 | NS2B | 4,224–4,613 | 390 | Cofactor for proteinase domain of NS3; proteolytic processing. | [35] |
8 | NS3 | 4,614–6,464 | 1,851 | Protease/helicase. | [39,40] |
9 | NS4A | 6,465–6,914 | 381 | Viral RNA replication and amplification. | [35] |
10 | 2K | 6,846–6,914 | 69 | Peptide generated by cleavage at the N terminus of the NS4B signal sequence. | [35] |
11 | NS4B | 6,915–7,667 | 753 | Facilitates viral replication complexes; counteracts innate immune responses. | [35] |
12 | NS5 | 7,668–10,376 | 2,709 | Methyltransferase; RNA-dependent RNA polymerase. | [41] |
13 | 3′-UTR | 10,380–10,807 | 427 | Facilitates viral replication and translation. | [34] |
Phylogenetic analysis of complete genomes of the ZIKV (Fig. 3)42 shows two distinct clades: African and non-African or Asian. The African clade is subdivided roughly into two further clades, one for East/Central Africa and another for West Africa. The genomic sequences of the Brazilian variety are closely tied to the Cambodian and Malaysian genomes in the non-African clade, thus implying that the Brazilian ZIKVs belong to the Asian clade. The phylogenetic tree shows that the Micronesia genome of 2007 is part of this Asian clade and indicates, as reasoned by Duffy et al.12 and Haddow et al.,13 that the virus was probably carried from Asia by a viremic human to Micronesia or by a stray infected mosquito that was carried into Micronesia by the ubiquitous communication network, a probable course that could be easily replicated in case of other viral epidemics in the future.
The difference between the African and Asian ZIKV genomes is more clearly brought out in a two-dimensional (2D) representation of the nucleotide sequence.42 The 2D graphical representation for two genomes of the ZIKV–one from the Central African Republic in 1976 and another from Brazil in 2015–are shown in Figure 4.42,43 Since the plot follows the sequence in order and since the structural gene sequences constitute 2,489 (23.03%) bases out of 10,807 bases of a typical genome (Table 4), we can see that for about a quarter of the sequence comprising the structural genes the two curves overlap, but then there is a divergence that carries on to the end, implying significant differences in one or more of the NS genes. A choice of different axes assignments and counting methods within the 2D graphical representation systems show dramatic differences between the representations of the genomes of African and Asian lineages arising from differences in their base distributions.42,44 The two methods allow quantitative measures of the differences and permit mathematical characterization of the genomic sequences.
In terms of nucleotide sequence identity between the various Zika strains, sequence alignment shows that the conserved bases amount to 87.06% for the strains comprising the African clade compared to 92.6% for the Asian clade; overall, the conserved bases amount to 79.05% of total bases.42 The higher conservancy level seen in the Asian clade strains is considered as arising from the much lesser time they have had to change through mutations, whereas the African clade strains, being comparatively older by decades, have had the time for many mutational changes.42
Lanciotti et al.45 have shown that the Uganda MR766 ZIKV and the Yap Island Zika strains have 96% conservancy in their protein sequences, which the authors suggest could be the result of selective pressures arising from virus replication adapted to vertebrate hosts and arthropod vectors. This is also borne out by the Ka/Ks (asynonymous to synonymous) ratios for the various coding regions of ZIKV computed by Zhu et al.35 which showed that these ratios for ZIKV strains were comparatively low, implying that these genes were under stabilizing selection pressure. Note, however, the observations of Giri et al.46 from their study of the ZIKV proteome (strain MR766) that revealed abundant intrinsically disordered regions in the capsid, NS2B, NS3, NS4A and NS5 proteins that contribute to structural plasticity and functional diversity in their role in mature particle formation and replication.
The ZIKV proteins
The complex polyprotein of the ZIKV bears low similarity to the polyproteins of other closely related flaviviruses, viz., SPONV (68.3% to 69% nucleotide similarity in the strains studied and DENV2 (58.1% to 58.9% nucleotide similarity).35 The 10 structural and NS proteins contain multiple transmembrane domains, with the majority being accounted for by NS2A, NS2B, NS4A and NS4B.35 A 2K protein is generated by cleavage at the signal sequence of the NS4B; Kuno and Chang has discussed the cleavage sites in ZIKV and related other viral genomes in detail.34 The different genes encoding for the proteins making up the ZIKV play important roles in viral pathogenicity, replication and assembly, some of which are briefly described below.
PrM/M—A protein that along with the E protein forms hetero-dimers, essential prerequisite for formation of immature virions. Subsequently, the prM is cleaved and replaced by the M protein to produce and release mature virions.
E—A surface protein that is involved in viral attachment, fusion, penetration and hemagglutination. One hundred and eighty E proteins make up the icosahedral shell of the virion. The Zika virion is different from other flaviviruses, in that around 10 amino acids surround the Asn154 glycosylation site in each of the Zika E proteins.36 The E protein exists as a dimer in the mature virion, each protein having three domains: Domain I, harboring the glycosylation sites; Domain II, serving as the fusion protein; and Domain III, flanking one side of domain I and serving as the major antigenic region in the E protein. The receptor binding site is located in domain III, making it an important target for therapeutics and vaccine development.
NS1—The first NS protein, NS1, plays a complex role in viral replication and pathogenesis. First reported in the sera of DENV-infected patients, it is well conserved among all the flaviviruses. As reported by Muller and Young,37 NS1 protein is found in multiple oligomeric forms and in different cellular structures, such as the cell-membrane bound form, on the cell surface and as a secreted soluble hexameric lipoparticle. It facilitates viral replication through its role as an essential co-factor. The secreted form of NS1 is implicated in immune evasion, while secreted and cell surface NS1 and the antibodies they elicit are believed to play contradictory roles of prevention and pathogenesis in the infected host.
Freire et al.38 measured the synonymous codon usage for a range of ZIKV strains and found significant differences in codon usage for the entire polyprotein in the African and Asian lineages. In particular, for NS1, which, amongst the samples studied, had 91.8% amino acid conservancy, codon usage bias in recent Asian lineage strains was higher as also in NS4A, and codon adaptation index that measures efficiency of adaptation to a host was also higher for humans and mosquitoes. Freire et al.38 also observed high levels of secretion of NS4A proteins, like for NS1 proteins, by infected cells, which they believe is significant since both NS1 and NS4A play important roles in viral replication, while NS4A helps viral survival by inhibiting cell death by up-regulation. Zhu et al.35 suggest that NS1 is required to initiate RNA genome synthesis.
NS2A, NS2B, NS4A, NS4B—These NS proteins are small and hydrophobic, but with functions not yet well understood and having no known enzymatic motifs.35 A comprehensive analysis by the same authors of the closely related Zika and SPONVs in terms of phylogenetic relationships showed that while the tree topology was almost similar for all the proteins, in the case of NS2B there is a difference, which the authors suggest probably arose from gene recombination events between the two types of viruses. The NS2B protein is also involved in cleavage of the viral polyproteins through its interaction with the C-terminal protease domain of NS3.
NS3 is a multifunctional replication-oriented protein that, along with NS5, encodes the major viral enzymes of flaviviruses. The Nterminus of NS3 is involved in protease activity, while the C-terminal domain is involved in ATPase, helicase and other enzymatic activities. The C-terminal NS3 helicase is crucial to the survival and life cycle of ZIKV, and, therefore, constitutes suitable target for antivirals. Ramharak et al.39 have shown through molecular dynamics studies that an inhibitor like NITD008 effectively constrains ZIKV replication in vitro and in vivo. Jain et al.40 have shown through their NS3 structure determination that the NS3 helicase is closely similar to other flaviviruses, like DENV, and has three domains of roughly equal size (∼145 residues). Domains 1 and 2 comprise tandem α/β RecA-like folds, characteristic of the helicase superfamily. ATP binds to the bottom of the cleft between domains 1 and 2 and the RNA is accommodated in a tunnel between domains 1 and 2 and domain 3; this domain has been implicated in interactions with the RNA-dependent RNA polymerase NS5 in other flaviviruses. Their studies with FTMap determined that there are two prominent drug or ligand binding sites that occur between domains 1 and 2 and at the junction of domains 1 and 3. Moreover, the two sites are situated close enough that it may be possible to design inhibitors that span both sites. Molecular dynamic studies by Oguntade et al.47 also determined three potent inhibitors of the NS3 helicase (Lapachol, HMC-HO1α and Ivermectin) binding at the ATPase and single-stranded RNA site.
NS5—The largest of the ZIKV proteins, NS5 is a critical component in replication of the ZIKV RNA genome. The N-terminal part contains a methyltransferase (MT) domain, followed by a short linker that connects to the C-terminal part that contains the RNA-dependent RNA polymerase. Translation of the polyprotein is facilitated by the MT that adds the 5′-RNA cap structure, while the RNA-dependent RNA polymerase functions to initiate RNA synthesis; the MT also plays a role in inhibiting host innate immunological response. Zhao et al.41 determined that, structurally, the ZIKV NS5 shows remarkable similarity to other flavivirus NS5s and active sites are well conserved. These findings have indicated nucleoside analogues that can inhibit the polymerase activity of yellow fever virus, WNV and DENV and can also inhibit the ZIKV.
3′-UTR—This region has a role in viral replication and translation, and defects in the conserved regions can significantly affect the survival and pathogenicity of the virus.34
Genetics of the ZIKV epidemic
While a plethora of research on ZIKV has consumed the scientific world in the last 2 years following the ZIKV pandemic, the abiding problem that is still not resolved is the cause behind the sudden epidemic form of ZIKV as it spread to Oceania and South America. Does the answer lie in any significant changes in the virus, or does the answer lie in some characteristics of the host population? On the latter possibility, Kindhauser et al.3 speculated that perhaps the African and Asian populations being exposed to many diseases with similar symptoms, such as malaria, DENV, chikungunya and the like, over many generations had developed immunological characteristics that thwarted the neurotropic effect of ZIKV, but substantive proof of this assertion is yet to be established. As pointed out by Russel,48 increase in vector population also does not explain the epidemic since the Aedes group of mosquitoes have been present in tropical and sub-tropical South America, supporting DENV and chikungunya, for many years.
Considerable amount of effort has been devoted to the first alternative. Zhu et al.35 in their detailed study of Asian lineage pre-epidemic and epidemic strains of ZIKV found 24 amino acid substitutions in various proteins of the epidemic strain polyprotein, four of which (T773M, Y2082H, L2451S and T2630V) affected the hydropathy profile. Comparison with the African lineage displayed many more (75) amino acid substitutions, most of which had to do with the separation of the African and Asian lineage. However, 15 substitutions were specific to the epidemic strains. They found V603I and D679E substitutions in domain 3 of the envelope protein and found the I and E amino acids in those positions in all epidemic strains. They also found differences in the RNA secondary structures of the 5′- and 3′-UTRs of epidemic ZIKV compared to the pre-epidemic strains.
Russel suggested that codon usage bias in the epidemic strains could be the source of the increased pathogenicity of the ZIKV.48 He also reported that immune enhancement by pre-existing anti-flavivirus antibodies could be a contributing factor, as in the case of DENV, making the virus more pathogenic. Combination of both these factors could have led to the increased virulence observed for ZIKV infections in South America. Freire et al.38 detailed codon usage differences in the NS1 gene as a contributing factor to the Zika epidemic.
Ganguly and Ganguly determined by BLAST sequence analysis similarities in sequences of ZIKV NS4B and the human astroactin2 (astn2) gene.49 The astroactin2 protein is expressed at high levels during fetal development, and mutations in it can be associated with microcephaly in humans. The authors hypothesized that since both ZIKV NS4B and human astn2 are transmembrane proteins, they may co-localize and interact at pre-translational stages to cause microcephaly. However, why such situations did not develop in Africa or Asia, where presumably astn2 is also active, is not clear.
Perhaps the answer to the questions posed in the beginning of this section could be that both aspects, changes in ZIKV in the epidemic forms and the immunological status of the local host population, could form the lethal combination that gave rise to the neurological damages noticed in the epidemic ZIKV infections.
Drugs and vaccines for ZIKV
No drugs or vaccines are available against the ZIKV as of yet, but several strategies are being pursued by researchers on their design and development.46,50–55 Among the most recent, Balasubramanian et al.,56 for example, have determined three compounds-quinacrine, mefloquineand GSK369796-that inhibit viral replication and therefore show anti-viral activity against DENV2 and ZIKV; Ramharack et al.39 suggested the NS3 protein as suitable target for inhibitor design.
On the other hand, considering that for some of the other human infecting flaviviruses (e.g., the WNV and the JEV) vaccines have been available for some time, the National Institute of Allergic and Infectious Diseases (NIAID) of the National Institute of Health (USA) worked on developing a DNA vaccine against ZIKV based on the WNV vaccine.57 Phase 1 trials having given encouraging results, the vaccine was entered into a Phase 2 critical trial in March 2017, results of which are awaited. In the meantime, the Walter Reed Army Institute of Research (USA) launched a Phase 1 trial of a purified inactivated vaccine against the ZIKV based on their previous experience with DENV and JEV. A live-attenuated ZIKV vaccine developed at the NIAID is undergoing Phase 3 trials in Brazil, and several other investigational approaches are under way. At last count, ClinicalTrials.gov,58 an arm of the National Institute of Health, listed 16 studies for ZIKV vaccines. Many private firms, such as GlaxoSmithKline Pharma (USA) and SEEK (London), are working on various strategies for a ZIKV vaccine,57 while Bharat Biotech (India) is reported to be undertaking pre-clinical trials for a Zika vaccine, Zikavac.59
There are many other ideas for a ZIKV vaccine design. Taking a cue from the JEV situation, Zhu et al.35 recommended the glycosylation site in the prM-E complex, where a single amino acid substitution may elicit increased humoral host immune response, and domain 3 of the E protein, which contains the receptor binding site, as useful targets for vaccine design. Peptide vaccine that is strongly focused on generating appropriate immune response is an alternative strategy that has been put forward by several authors,60–62 though some technical problems remain.63
Shawan et al.64 predicted peptide vaccine targets using immunoinformatics tools within the Immune Epitope Analysis Resource and Database to identify peptides at the ZIKV protein sequence positions 121 and 117–137 as most potent B cell linear and conformational epitopes, respectively. They also predicted highly potent T-cell epitopes at protein sequence position 250–258. Dey et al.65 performed an analysis spanning conserved surface exposed regions with linear and conformational epitopes from a selection of complete and partial ZIKV envelope proteins, and identified a set of three peptide segments that could form the basis of peptide vaccines.
The issue is much broader than just to design a drug or vaccine for the ZIKV. The issue is the strategies to adopt to combat recurring bouts of epidemics from existing or new, zoonotic viruses and management of those strategies. Basak and Nandy have recounted the difficulties and costs associated with development of effective drugs and vaccines for use in the field and computational strategies that have been devised to combat these issues.66 Bhattacharjee and Basak have outlined the strategies that could be adopted for drug development against particular viruses like ZIKV,67 and Nandy and Basak have outlined the importance of management of the strategies,68 albeit in another viral context. The recent work by Dey et al.65 establishing a vaccine against the ZIKV is one strategy of peptide vaccine design to contain and prevent infections from the ZIKV.
Future research prospective
As this review shows, the reasons behind the sudden transformation of the ZIKV from an apparently benign form to one with severe neurologic complications continues to remain a mystery. It is sure to continue to be a main line of research activity, since the underlying causes could have implications for other viruses, and perhaps other flaviviruses, to also become neurotropic. One of the aspects that will come under close scrutiny arises from the ZIKVs’ close proximity to DENV type 2, viz., whether the ZIKV will also show possibilities of antibody dependent enhancement, an affliction that has caused severe hemorrhage in repeat DENV patients, often leading to fatalities. The next mosquito season may shed some light on that.
The most intense research will surely continue in the areas of drug and vaccine development against the ZIKV. The success of the off-the-table vaccine against Ebola has raised hopes that a similar result could be anticipated with the ZIKV in view of the available vaccines and research programs in the case of the other human infecting flaviviruses, but no drugs or vaccines have reached the clinical use stage as yet.
For some researchers with a more fundamental outlook, the rampage of ZIKV gives rise to a need to understand, at some basic level, what causes these sudden eruptions of virulent strains. We have seen cases of the swine flu (i.e. H1N1), the SARS and MERS epidemics, the Ebola crises and myriad other epidemics, of which the ZIKV is the latest and one with very far-reaching consequences. The question is whether we can extract some lessons from these experiences and prepare mankind to defend against possible epidemics reasonably earlier,69 whether there are perceptible clues that could help in this task, or whether we are constrained to always fight the conflagrations after the events. Given the growth in human population, climate change, insect menace, increasing urbanization and other concomitants of civilization, these are issues to consider, however remote the solutions may seem today.
Summary
The saga of the ZIKV is perhaps only in its beginning stages. From its identified origins in an obscure tropical forest in Uganda, it had spread through its natural vectors like A. aegypti and other Aedes species mosquitoes and unwitting travelers who may have carried the virus to new locales. Within half a century the virus had already made its way to other countries in tropical Africa and in South and South East Asia, Indonesia and the Philippines. The spread of the new virus evoked only sporadic illnesses reminiscent of DENV, chikungunya and the like, thus masking its nature and identity enough to be considered benign when recognized.
All that changed after epidemics in 2007 and 2013 in certain Pacific islands and in 2015–2016 in Brazil and several Latin America countries. Unusually high levels of microcephaly in fetal and neonatal cases, GBS and neurological disorders, recognized as being associated with ZIKV infections, raised serious concerns. The high level of urbanization that facilitates easy contamination, global warming that increases the reach of the vectors to newer areas, mega events like the Olympics that let people from various countries come into close contact, heightened levels of travel and shipments, all could contribute to further spread of the virus.
The reason that the virus that was relatively benign in the pre-epidemic period and suddenly became so highly pathogenic as to cause neurological dysfunctions in fetuses and neurotropic disorders in children and adults is yet to be understood. Amino acid substitutions could be one key; other keys may include local host immunologic status, vector infectivity and perhaps other as yet unrecognized issues. It is also not understood what causes only 1 in 10 fetuses of Zika-infected mothers to develop birth defects.11
ZIKV, a member of the Flavivirus family, is a positive-sense single-stranded RNA virus whose genome consists of a polyprotein that codes for 10 structural and non-structural proteins. Genomic analyses have revealed several mutations in the genomes of the virus in Africa, Asia and the Americas that indicate a pronounced shift between the African and Asian lineages, but the American genomes line up quite well with the Asian strains. Phylogenetic analysis reveals distinct clades for the African and Asian lineages; comparison with other human infecting flaviviruses (Fig. 5) shows each member of the family in distinct clades, in which DENV type 2 is found closest to ZIKV.70
Repeat infections in case of DENV can cause antibody-dependent enhancement, leading in some cases to severe hemorrhage and death. The Zika epidemic is too recent to estimate the danger of a second infection, but since ZIKV and DENV are of the same Flavivirus family, with ZIKV being phylogenetically closest to DENV2 among the four DENV types, the possibility of antibody-dependent enhancement-type reactions and symptoms cannot be ruled out at present.
However, whatever may be the reasons behind the transformation into a highly pathogenic form, development of suitable drugs and vaccines against ZIKV has to take priority. Several small molecules have been proposed to inhibit viral replication and multiple vaccine candidates are in various trial phases and more are on the way. Peptide vaccines could hold one key to longer lasting solutions since these are predicated upon conserved segments,65 but the statistics remain poor at this time.63
While Zika viral infections could be on the downswing in mid-2017, the trials and tribulations of the last 2 years show the importance of understanding viral epidemics and vaccine preparedness and whether the entire exercise could be done faster in case of new outbreaks.69 New strategies, preferably computer-assisted ones,66,67 are required to manage the burden of viral epidemics that may arise from new and emerging viruses that have adapted adequately to infect humans. In the meantime, only governmental efforts to curtail mosquito prevalence and issuance of advisories for citizens remain the main efforts to combat the menace of the new virus. Institutions like the CDC and WHO provide timely alerts and warnings, and individuals have to protect themselves from mosquito bites and contacts with infected persons – all until a reasonably dependable regimen against the virus is devised.