Role of antenatal plasma cytomegalovirus DNA levels on pregnancy outcome and HIV-1 vertical transmission among mothers in the University of Zimbabwe birth cohort study (UZBCS)

The UZBCS aims to investigate the role of maternal comorbidities, including co-infections with persistent viruses such as HIV, CMV, hepatitis B virus, and other infectious or non-communicable diseases including maternal nutritional status on pregnancy outcomes, infant mortality, development, immunity and health. By design, approximately 50% of the expecting women the UZBCS are HIV-infected. Briefly, at enrolment all women answered a structured questionnaire aiming at a comprehensive clinical, socio-demographic, environmental and household characterization of the research participants. Further, socio-economic information comprising employment status, family monthly income, money set aside for food were recorded including general household food security. Date for cART commencement and compliance were recorded in HIV-infected women. According to Zimbabwean national guidelines, all HIV-infected women should be on lifelong cART (Option B +), but in practice pregnant women often do not receive a timely HIV diagnosis. The current standard of care for all Zimbabwean HIV-infected pregnant women to prevent HIV MTCT consists of (non)–nucleoside reverse transcriptase inhibitors; TENOLAM-E (Tenofovir, Lamivudine and Efavirenz. Mothers breastfeed as long as they wish to. However, exclusive breastfeeding is encouraged during the first six months of life.

All HIV exposed infants are commenced on Cotrimoxazole prophylaxis until they stop breastfeeding or they test HIV-PCR positive, whichever occurs first. Upon detection of HIV-1 infection, infants are immediately commenced on cART, usually comprising the protease inhibitors Lopinavir/ritonavir and nucleoside reverse transcriptase inhibitors, Zidovudine and Lamivudine.

The UZBCS recruited 600 HIV-infected and 600 HIV-uninfected pregnant women at least 20 weeks of gestation from February 2016 until June 2019. Mother-infant dyads will be followed for 2 years, with an expected study completion date in June 2021.

Potential participants for the cohort were identified during routine antenatal care visits at any one of the four out of a total of twelve City of Harare Polyclinics, situated in the South-western high-density areas of Harare namely, Kuwadzana, Rujeko, Budiriro and Glenview. Residents of these communities are of relatively poor socio-economic status. Follow-up visits of the mother-infant dyads were performed at delivery, within 10 days of life and 6, 10, 14 and 24 weeks postpartum. Date and mode of delivery, birth weight and length, feeding practices and information on the general health and development of infants were also collected.

Data and bio-samples were available from the first 527 mothers recruited consecutively from February 2016 and August 2017, of which 280 were HIV-infected. Due to financial  limitations, CMV-DNAemia measurements were only possible in a subgroup of pregnant women. We first selected all mothers who transmitted HIV to their infants by 6 months of age (n = 11) as MTCT cases. A total of 120 HIV-infected but non-transmitting mothers were randomly selected as controls by a computer Pseudo Random Number generated algorithm. Three of these women gave birth to live twins. Depending on respective analyses’ outcomes we referred to this group as 120 HIV-infected but non-transmitting mothers or 123 infant-mother dyads. An additional 46 HIV-uninfected controls and their infants were also randomly selected using the same procedure.

Ten millilitres of maternal venous blood was collected at enrolment. Maternal HIV diagnosis was done using qualitative rapid immunochromatographic assays, SD Bioline HIV-1/2 3.0 (Standard Diagnostics Inc., Kyonggi-do, South Korea) and Abbott’s Determine® HIV-1/2. Western Blot was the tie breaker for any indeterminate test results.

Full blood counts were determined from whole ethylenediaminetetraacetic acid (EDTA) blood samples using a Mindray© Haematology 3-part differential, 16 parameters BC3600 Analyser (Shenzhen, China). For diagnosis of anaemia in pregnancy, the World Health Organisation (WHO) definition was used (haemoglobin < 11.0 g/dL) [21].

Absolute CD4⁺ T-lymphocyte counts in EDTA blood samples were enumerated within a maximum of 6 h after sample acquisition for all HIV-infected mothers using a Partec Cyflow counter (Cyflow, Partec, Munster, Germany).

For analysis of HIV-RNA and CMV-DNA loads, blood was centrifuged for 5 min at 3000 rpm and the plasma was aliquoted in appropriately labelled cryo-vials and stored at − 80 °C until testing.

Total CMV nucleic acids were extracted from 200 µL plasma using the QIAamp MinElute Virus Spin Kit (Qiagen, Hilden, Germany). Then, 60 µL of total viral nucleic acids including CMV-DNA were eluted and immediately stored at − 80 °C for subsequent testing. CMV-DNAemia detection and quantification was performed by quantitative PCR (qPCR) using the RealStar CMV PCR kit v1.0 (Altona Diagnostics, Hamburg, Germany). CMV-DNA was quantified using the QuantStudio 3 Real-Time PCR System (Applied Biosystems, CA). The detection limit was 1 copy per mL.

For HIV, viral nucleic acids were extracted from 1 mL maternal baseline plasma and HIV-1-RNA quantified using an automated TaqMan Roche Amplicor 1.5 Monitor Test (Cobas AmpliPrep/Cobas TaqMan, Roche Diagnostics, Branchburg NJ), according to the manufacturer’s instructions. The detection limit was 20 copies per mL.

Adverse birth outcomes included preterm birth (< 37 weeks of gestation), low Apgar scores at 5 min (< 7) and low birth weight (LBW, < 2500 g), weighed within the first hour of life, before significant postnatal weight loss had occurred. Head circumference and birth lengths were also measured in centimetres. Z-score transformation of infant birth weight and birth length followed normal distribution of WHO reference data of 2006. Transformation was performed using the R package “zscorer”.

Venous blood (EDTA) or heel prick blood spots were collected and preserved on 903 protein saver card (number 105311018) at delivery, 10 days and 6, 10, 14 and 24 weeks. Every infant blood sample of each study visit was processed and stored as dried blood spots and plasma at − 20 and − 80 °C, respectively for further evaluation, including HIV and CMV assessments. Infants’ HIV infection was detected using a qualitative 1.5 Roche Amplicor HIV-1 proviral DNA PCR kit (Roche Diagnostics Incorporation, Branchburg, New Jersey).

Data were entered and managed using Research Electronic Data Capture (REDCap v 8.0, © 2020); http://​www.​redcap.​uzchs.​ac.​zw/​redcap/​. Quality assurance on the accuracy of data entry included independent double entries and verification in cases of discrepancies.

Parameters from groups of HIV-infected/-uninfected and/or CMV-DNA positive (viremic) and negative (aviremic) women were compared using the Kruskal Wallis test, Mann–Whitney U test, Chi-squared test and Fisher exact test where appropriate. For all serology positive test results, undetectable levels of HIV-1-RNA load or CMV-DNA were assigned the value zero. For multivariate linear and logistic regression analyses, the following predictors: CMV-DNAemia of > 50 copies per mL, HIV-1-RNA load, years since HIV diagnosis, ongoing cART use duration and maternal age, all at the time of enrolment were tested.

For infant outcomes, all infants (including twins) were included, and for each infant the respective maternal parameters were used (resulting in usage of the same maternal parameters for both twins). For maternal outcomes (e.g. prediction of maternal HIV-1-RNA load) the mothers with twin deliveries were counted once.

Automated parameter elimination for optimization of the Akaike information criterion using the “glmulti” R package was done. Due to limited statistical power, we did not consider interaction between predictors. All calculations were performed in R Studio 1.2.5001.

From 527 pregnant women recruited between March 2016 and August 2017, 280 (53%) were HIV-infected and 247 (47%) were HIV-uninfected.

For the antenatal plasma CMV-DNA analysis, we selected all 11 HIV-infected mothers with subsequent HIV-MTCT as cases (HIV transmitters) and randomly selected 120 HIV-infected but non-transmitting mothers and their 123 infants (3 twin pregnancies) as controls, as well as 46 HIV-uninfected mothers and their 46 infants (no twin pregnancies). A total of twelve stillbirths were observed, of which 9 were HIV exposed but were not tested for in utero HIV infection, Fig. 1.

No relevant differences were observed between the randomly selected mothers included in the CMV-DNA analysis and the rest from the UZBCS population (Additional file 2: Tables 1, 2).

Baseline characteristics stratified by HIV status of all the pregnant women included in the CMV-DNA analysis (N = 177) are presented in Table 1. HIV-infected pregnant women were significantly older (p = 0.031) but showed similar anthropometric measures and socio-demographic characteristics with regards to family income, household size and number of infants < 5 years old living in the household. As expected, HIV-infected pregnant women with CMV viremia had lower haemoglobin levels (p = 0.02), Additional file 2 : Table 3).

Of the 131 of HIV-infected pregnant women, regardless of the vertical transmission status, 28 (21%) had their first diagnosis of HIV done at enrolment into our study, and hence they were cART naïve. 103 were already on cART at enrolment, and of these, 27 (26%) were on cART for < 30 days, [median (1st quartile-3rd quartile); min–max]; [11 [2‐24]; 1–29] and 76 pregnant women were on cART for > 30 days, [799 (141–1677); 32–4327], with self-reported cART adherence rates of 100% and 87.5%, respectively. HIV-RNA load of ≥ 1000 copies/mL were observed in 54/129 (42%) of the pregnant women (2 cases of missing data). As expected, cART use was strongly associated with lower HIV-RNA load, but no further trends were detected (Additional file 2: Table 4).

Plasma CMV-DNA was detected at comparable frequencies in HIV-uninfected and -infected pregnant women (HIV-uninfected: 10/46, 21.7%; HIV-infected: 32/131, 24.4%; p = 0.841), although a non-significant association of higher CMV-DNA levels with HIV-infection was observed (Table 1).

In a multivariate analysis, neither HIV status nor maternal age nor socio-demographic parameters such as number of children under five years in the household were significantly associated with CMV-DNA load (Additional file 2: Table 5). CMV-DNA load of > 1000 copies/mL were observed in 6 out of 177 women (3.4%), whilst higher load of > 10,000 copies/mL was detected in only one HIV-uninfected woman. CMV-DNA levels were significantly higher in immunosuppressed pregnant women with CD4 < 200 cell per µL (p = 0.018, Mann–Whitney U test).

In our pilot study, 130 infants born of HIV-infected pregnant women were examined for HIV-MTCT (Fig. 1). 11 with vertical HIV transmission events were included as cases. In comparison with the control sample of 119 infants without MTCT, CMV-DNAemia was associated with HIV-MTCT, since MTCT was observed in 6/32 (19%) CMV-DNA viremic mothers compared to only 5/98 (5.0%) of CMV-aviraemic mothers (p = 0.026, Fig. 2).

This association was confirmed in a multivariate analysis. A non-significant association of higher HIV-MTCT with mothers having CMV viraemia of ≥ 50 copies/mL and MTCT independent of maternal plasma HIV-1-RNA load was observed before parameter elimination (OR 3.62, CI 0.81–16.29, p = 0.085, Table 2). However, after parameter elimination, the association of CMV viremia ≥ 50 copies/mL at enrolment with HIV-MTCT was significant (OR 4.02, CI 1.09–15.30, p = 0.035, Table 2).

Associations of different parameters with plasma HIV-1-RNA load were examined in HIV-infected but non-transmitting mothers. In a multivariate linear regression analysis, CMV-DNAemia of ≥ 50 copies/mL and also CMV-DNA load (copies/mL) as continuous variable were significantly associated with higher HIV-1-RNA load (both p = 0.002) while as expected cART usage correlated with lower HIV-1-RNA load (Table 3, Fig. 3, Additional file 1: Fig. 1). These parameters remained significant after automated parameter elimination.

We tested whether CMV levels were a predictor for preterm births before 37 weeks gestation in the sample of 123 infants born of HIV-infected but non-transmitting mothers (120 mothers; 3 twin pregnancies) and 46 infants born of 46 HIV-uninfected mothers. Multivariate logistic regression analysis showed a non-significant association (p = 0.269) of more deliveries before 37 weeks of pregnancy among mothers with CMV-DNAemia ≥ 50 copies/mL (Additional file 2: Table 6).

When we limited the multivariate analysis to infants born of HIV-infected but non-transmitting mothers, this trend showed a borderline statistical significance (OR 2.71, CI 0.94–7.88, p = 0.063, Table 4). This association was robust to parameter elimination (OR 2.37, CI 0.88–6.29, p = 0.083, Table 4). In the same analysis, time since the HIV diagnosis was a significant predictor for delivery before 37 weeks (OR 0.73, CI 0.55–0.91, p = 0.011, Table 4), independent of maternal age.

Among HIV-infected pregnant women, delivery before 37 weeks gestation was frequent (34/134, 25.4%) with lower rates observed among those with successful cART with HIV-1-RNA load of < 20 copies per mL (7/39, 17.5%). We limited the logistic regression analysis to HIV-infected but non-transmitting mothers under successful cART (≤ 20 copies/ mL). In this collective, no association of more frequent deliveries at < 37 weeks with CMV-DNAemia ≥ 50 copies/mL remained (p = 0.861, Additional file 2: Table 7).

An association of lower birth weight of infants born from HIV-infected mothers and/or mothers with CMV-DNAemia was noted but failed to reach statistical significance (p = 0.450). Further, antenatal CMV-DNAemia was associated with lower birth length in some but not all analyses (Table 1, Additional file 2: Table 1).