Phylogenetically HIV can be classified into two types; type 1 (HIV-1) and type 2 (HIV-2) [65]. Both viral types cause AIDS. HIV-1 is the first in the class of human retroviruses and accounts for most of the world’s HIV in-

fections. Its origin can be traced back to a Simian Immunodeficiency Virus (SIV) isolated from a Chimpanzee (cpz) sub-species, Pan troglodytes troglodytes (SIVcpz) cross species transmission to humans [70-72] . HIV-2 is the second in the same class of human retroviruses but is largely confined to West Africa. The primate reservoir of HIV-2 is sooty mangabey, Cercocebus atys (green monkey) [73,74] . Thus, (SIVCPZ) is closely related to HIV-1, while SIV from sooty mangabey (SIVSM) is closest to HIV-2 [75]. HIV-1 and HIV-2 are closely related viruses with nucleotide sequence homology of 58%, 59% and 39% in the gag, pol and env genes, respectively [76]. Despite similar modes of transmission, HIV-2 is not as efficient in transmission horizontally and vertically [65,77,78] . Relative to HIV-1, HIV-2 has a reduced rate of disease development and has shown natural resistance to readily available non-nucleoside reverse transcriptase inhibitors (NNRTIs) [79] . Genetic recombination between HIV types-1 and-2 has been reported [80] . Distinction of HIV types is essential for accurate surveillance, diagnosis as well as administration of appropriate antiretroviral therapies.

Phylogenetic analysis of HIV-1 suggested that zoonosis occurred on at least three independent cross species transmission events from chimpanzee, Pan troglodytes (pts), Pan troglodytes troglodytes (ptts) or gorilla (gor) resulting in four distinct HIV groups called the major (M), outlier (O), non-M/non-O (N) as shown in Figure 3. Studies have estimated the timing for the zoonosis of each lineage of groups M, O, and N at around 1931, 1920 and 1963, respectively [82] . Group M is responsible for more than 90% of the world HIV infections [83] . Interestingly, the genetic analysis of sequences from clinical materials obtained from members of a Norwegian family infected earlier than 1971 showed that they carried viruses of the group O mainly restricted to West Africa [84] . HIV groups have genetic sequence differences of >40% in some coding regions [85] . More recently, a

new putative group, designated P, was reported in France from a Cameroonian female immigrant [86]. Group P viral sequences have been shown to form a distinct HIV-1 lineage with SIV sequences from western gorillas (SIVgor; Gorilla gorilla gorilla), suggesting that group P originated from gorillas [87] Reports have indicated that HIV-1 group P infections are rare, accounting for only 0.06% of HIV infections in Cameroon [88].

Unlike groups O, N or P, group M has been classified into subtypes.

Subtypes are phylogenetically linked strains of HIV-1 that are approximately the same genetic distance from one another. Group M has been classified into nine distinct subtypes, also called clades or genotypes, denoted with letters, A, B, C, D, F, G, H, J and K, thus making the development of effective blanket diagnostic and monitoring tests or vaccine a challenge [84,89] . Intersubtype variation is about 30% with respect to the env gene sequence and 15% for both the gag and pol genes sequences [90]. Different risk groups for HIV infection are associated with specific subtypes with intravenous drug users (IDUs) including the gay communities and heterosexual population generally acquiring subtype B and non-B subtypes, respectively [91-93] .

Within each subtype numerous HIV-1 variants exist that exhibit minor intra-subtype genetic diversity of within 10% called sub-subtypes [94]. These are distinctive HIV-1 lineages that are closely related to a particular subtype lineage, but are not genetically distant enough to justify calling them new subtypes. Sub-subtypes are denoted by numerals for instance in the case for subtype A these have been named A1, A2 or A3 [95] . Recent studies have demonstrated the need for HIV classification using full-length genomic sequences if new distinctive subtypes are to be accurately identified rather than relying on sequencing of different viral gene fragments as has been the standard.

Full genome sequencing of HIV has resulted in the discovery of circulating and unique recombinant forms (CRFs) and URFs, respectively. Recombinants are unique in the sense that they may be described in isolated individuals without any evidence of epidemic spread. To be classified as a CRF, a virus strain must be detected in at least three epidemiologically unlinked individuals and must be capable of establishing an epidemic on its own. Thus, these mosaic HIV-1 strains reflecting a mixture of subtypes circulating in different populations may have altered pathogenic and/or transmissibility properties [96] . CRFs are referred to by their number that is assigned according to the order of their discovery and the respective subtypes involved for example CRF02_AG or by their number(s) followed by the letters “cpx” (for complex), when more than two subtypes are involved for example CRF04_cpx or CRF06_cpx [97]. One of the most common group M CRFs is A/E, previously described as subtype E in Southeast Asia but was later renamed CRF01_AE following full HIV genome sequencing [98] . To date about 21 CRFs and several URFs have been described [99]. All CRFs together account for 18% of the world’s HIV-1 infections [100]. HIV-1 subtypes and recombinants may differ with respect to viral load levels [101] , transcriptional activation levels, disease progression and response to antiretroviral therapy including drug induced/natural resistance patterns [102-105] .

Previous Zimbabwean studies in the 1990s and early 2000 have observed a predominant subtype C [110-112] . The origins and evolutionary history of HIV-1 subtype C in Zimbabwe with respect to the pol sequence data sets generated from four sequential cohorts of antenatal women in Harare, from 1991-2006 has demonstrated increasing sequence divergence over the 15-year period. This data also indicates a most recent common ancestor date of around 1973 with three epidemic growth phases: an initial slow phase (1970s) followed by exponential growth (1980s), and a linearly expanding epidemic to the present day [113]. However, current HIV subtype(s) distribution in Zimbabwe remain elusive in view of the influence of the population movements in the past decade as result of the economic meltdown which could have facilitated subtype inter mixing. Generally, subtype specific variations may exist that influence differential transmissibility in different regions [114-116] .

Following sexual transmission of HIV the virus initially replicates locally in the vaginal or rectal mucosa [117] . Genetic diversity of HIV is lost during horizontal transmission and the virus gradually evolves towards a common ancestral sequence once in the new host [15,118] . Newly infected subjects acquire a subset of the viruses that were circulating in the transmitting partner; transmitted variants have less diversity and divergence [119] . Studies have correlated high HIV replication capacity with increased transmission rates [120] . Understanding the quantitative relationship between plasma HIV-1 RNA and HIV-1 transmission risk has been the cornerstone for ART preventive interventions that strive to reduce plasma HIV-1 levels that in turn reduce the risk of HIV-1 transmission [121] . Interestingly, Langerhans cells have shown minimal susceptibility to infection with subtype B virus but substantially greater sensitivity for infections by subtype C [122]. In the Rakai, Ugandan study, subtype A viruses have been shown to have a significantly higher rate of heterosexual transmission relative to subtype D viruses [123] . Differential subtype transmission efficiency may be important for HIV vaccine evaluation especially for the subtype-specific HIV epidemics in SSA. HIV-1-discordant couples are increasingly viewed as a valuable source of participants for HIV vaccine and prevention trials [124]. Curiously HIV-1 subtype C has been found to be the predominant subtype in sero-discordant couples followed by subtypes B and A, respectively [125] .

Increasing HIV-1 replication efficiency has also been related to a concomitant increase in HIV-1 diversity, which in turn has been the determining factor in disease progression [126,127] . Non-A subtype infections have been shown to progress to AIDS faster than those infected with subtype A [128] . More so subtype D has been associated with the most rapid disease progression relative to subtypes A, C and CRFs [129-131] . Pregnancy has been shown to increase the risk of female-to-male HIV-1 transmission by two folds [132] . Pregnant women infected with subtype C have been shown to significantly shed more HIV-1-infected vaginal cells than were those infected with subtype A or D [133]. Increased HIV-1 shedding has been correlated with a more complex population of HIV-1 quasi-species in the genital tracts of parturient women, which may increase the probability of transmission of fetotropic strains [134] . Identifying the specific genetics characteristics of successfully transmitted variants is also paramount in the development of an effective vaccine. Subtype and CRFs determination is generally done using the gag/env heteroduplex mobility assay (HMA) originally developed by Delwart [135] and later modified by Heyndrick et al., in the year 2000 [136] . Whole genome sequencing remains the gold standard although partial sequencing also gives good results at reasonable cost.