Background
Malaria is a major parasitic disease of public health concern in tropical and sub-tropical regions of the world. Human malaria is caused by
Plasmodium falciparum,
Plasmodium vivax,
Plasmodium ovale,
Plasmodium malariae, and
Plasmodium knowlesi [
1,
2]. Of these,
P.
falciparum occurs predominantly in Africa and is responsible for most of the severe and life-threatening forms of the disease [
3,
4]. The ability of
P. falciparum to develop resistance to almost all available anti-malarials, the emergence of insecticide resistant mosquitoes, and the non-availability of a malaria vaccine have been major obstacles to the effective control and eradication of malaria. Considerable progress was made in the control of malaria between 2000 and 2015 when global malaria mortality and incidence rates fell by 62 and 41%, respectively [
5]. The massive rollout of mosquito nets coupled with anti-malarial drugs and the use of indoor residual spraying of insecticides was attributed to the recorded success. Despite commendable gains, which unfortunately were not sustained, malaria still affects hundreds of millions of people globally [
6,
7]. About 228 million cases were estimated to have occurred worldwide in 2018, resulting in the death of over 400,000 individuals, most of which were in sub-Saharan Africa [
8]. Nigeria, the most populous nation in sub-Saharan Africa, is responsible for the highest burden worldwide: deaths of approximately 30% of children aged under 5 years, 25% infant mortality, and 11% maternal death. A major tool used by
P. falciparum parasites to undermine control measures such as chemotherapy, insecticide-treated nets, and the development of an effective vaccine is its characteristic phenotypic and genetic diversity.
Plasmodium falciparum exhibits enormous genetic diversity in natural populations, and this is evident in the number of antigenically diverse parasite populations found among infected individuals in malaria-endemic regions. Genetic diversity in the parasite population is characteristically a reflection of the transmission intensity in an area and is required for the acquisition of protective immunity against malaria [
9‐
12]. Individuals living in areas of high or intense malaria transmission are frequently infected with several complex mixtures of distinct parasite clones [
13‐
17]. On the other hand, the majority of infections in low transmission areas are monoclonal [
18‐
20].
Genetic diversity in natural populations of the malaria parasites has been characterized in several studies using polymorphic, unlinked genetic markers in the parasite genome. Notable amongst these markers are the genes encoding surface antigens found at the developmental stages of the parasite life cycle, particularly the blood-stage antigens merozoite surface protein 1 (MSP-1) and (MSP-2), which are known to be highly polymorphic. Several studies have utilized PCR typing of the
msp-2 locus alone or together with the
msp-1 locus to assess genetic diversity and complexity of
P. falciparum infections in different communities with varying transmission intensities and among infected individuals with different clinical presentations of malaria [
21‐
29]. However, little is known about the diversity of
P. falciparum infections at the level of the micro-environment, among members of the same household. The aim of this study, therefore, was to determine the genetic diversity of
P. falciparum isolates in children of the same household, living under the same roof, in Lafia, north-central Nigeria, using the highly polymorphic
msp-2 gene.
Methods
Study area and population
This study was conducted in Lafia, a city located within the middle belt region in north-central Nigeria. Lafia lies within Nigeria’s Guinea savannah ecological zone and in this area malaria is known to be endemic and perennial as described previously [
30,
31]. The main vectors serving as agents of malaria transmission in this region are
Anopheles gambiae sensu stricto (
s.s.),
Anopheles arabiensis,
Anopheles funestus,
Anopheles moucheti, Anopheles melas, and
Anopheles nili [
2,
32]
Children aged 9 months to 12 years who presented with symptoms compatible with uncomplicated or mild malaria at the Dalhatu Araf Specialist Hospital Lafia, between 2006 and 2011, were enrolled into the study on "determinants of disease outcome in P. falciparum-infected children" after satisfying the inclusion criteria as follows:(i) at least 2 children of the same household living under the same roof; and, (ii) they must have been residing in the same house for at least 6 months. Uncomplicated or mild malaria was defined as symptomatic malaria with presentations that included chills, pyrexia at presentation (axillary temperature > 37.5 °C) or history of fever within the preceding 48 h, presence of asexual forms of P. falciparum in peripheral blood smears and absence of any indication of severe illness or vital organ dysfunction.
Participation in the study was voluntary. Before being included in the study, the study protocol was explained to the parent/guardian of the children from each family, and then informed consent was obtained. Ethical approval was obtained from the Ethics Committees of the Nasarawa State Ministry of Health and the Dalhatu Araf Specialist Hospital, Lafia, Nasarawa State, Nigeria, with reference numbers S/MH/519/VOL.1/84 and DASH/ADM/MR/VOL.1/0001, respectively. There were no selection criteria in the enrolment process of children in the households as children were registered at random. The first child presented by a parent during the enrolment process, irrespective of age or sex, was documented as child 1 for that particular household; the second child presented was child 2 and so on. All malaria-confirmed cases were appropriately treated by the Hospital clinicians.
Sample collection and microscopy
Approximately 0.5 ml of venous blood samples were collected from each child for parasitological and haematological analyses. All samples were de-identified at the point of collection for the confidentiality of participants and only labelled with alphanumeric codes. Three drops of blood collected were blotted on labelled 3MM Whatman filter paper, air dried, individually sealed in plastic bags, and stored at room temperature until they were used for DNA extraction. Thick and thin blood smears were also prepared for microscopic examination. The slides were labelled and allowed to dry, after which the thin smears were fixed with methanol and subsequently allowed to dry. Slides were stained with freshly prepared 5% Giemsa stain for 20 min at room temperature [
33] and examined under the microscope. Parasitaemia was quantified relative to 250 white blood cells (WBC) on thick films and estimated as parasites per µl assuming a mean WBC of 8000 per µl of blood. Smears were labelled negative if no parasites were seen after examination of 200 high-power field (HPF) at 1000 × magnification on a thick blood film. Blood haemoglobin levels were estimated by haematocrit measurement of packed cell volume (PCV) using the micro-haematocrit centrifuge.
Parasite DNA extraction and genotyping of Plasmodium falciparum msp-2 gene
DNA was isolated from the dried blood spots on filter paper using the QIAamp® DNA Mini Kit (Qiagen, Hilden, Germany) following the manufacturer’s instructions; 150 μl of distilled water was used to elute DNA, which was then stored at − 20 °C until use.
All samples were genotyped for
P. falciparum msp-2 gene by nested PCR according to previously described amplification procedures [
31]. Briefly, a primary reaction and a second reaction (nested) was carried out on each sample. The primary reaction amplifies the entire coding region of the
msp-2 gene using the MSP2-1 and MSA2-4 primer pairs. Two sets of nested reactions were subsequently employed to amplify the central polymorphic region of the gene using the allele-specific primers FC 27-1/FC 27-2 and 3D7-1/3D7-2 for the FC27 and 3D7 allele types, respectively (Table
1). A third nested reaction was carried out with MSP2-2 and MSP2-3 primers to assess the frequency of isolates, which may be positive for
msp-2, but not specific for FC27 or 3D7 allele type due to the polymorphic nature of the central region. The primary PCR mixture consisted of a final volume of 25 µl that included 12.5 µl of Go Taq® Green Master Mix (Promega Madison, USA), 2.0 µl of each primer (10 µM) and 5 µl of genomic DNA. The reaction was performed using the following cycling condition: initial denaturation step at 94 °C for 5 min followed by 35 cycles of 10 s at 94 °C, 30 s at 57 °C and 40 s at 72 °C and a final extension step of 72 °C for 3 min. All nested reactions were performed in a final volume of 25 µl containing 2.0 µl of PCR product from the primary reaction, 12.5 µl of Go Taq® Green Master Mix (Promega Madison, USA) and 2.0 µl of each primer (10 µM). The PCR cycling condition was: initial denaturation step at 94 °C for 5 s followed by 30 cycles of 10 s at 94 °C, 30 s at 57 °C and 40 s at 72 °C, and a final extension step of 72 °C for 3 min. Primer sequences were synthesized by Invitrogen Life Technologies, UK. All PCR assays were performed using a BIOMETRA TB1 ThermalCycler (Biotron, Göttingen Germany).
Table 1
The sequence of oligonucleotide primers used in this study
Primary PCR |
MSP 2-1 | 5′-ATG AAG GTA ATT AAA ACA TTG TCT ATT ATA-3' |
MSP 2-4 | 5′-TTA TAT GAA TAT GGC AAA AGA TAA AAC AAG-3' |
Nested PCR |
MSP 2-2 | 5′-ACA TTC ATA AAC AAT GCT TAT AAT ATG AGT-3' |
MSP 2-3 | 5′- GAT TAT TTC TAG AAC CAT GCA TAT GTC CAT -3' |
FC27-1 | 5′-GCA AAT GAA GGT TCT AAT ACT AAT AG-3' |
FC27-2 | 5′-GCT TTG GGT CCT TCT TCA GTT GAT TC-3' |
3D7-1 | 5′-GCA GAA AGT AAG CCT TCT ACT GGT GCT-3' |
3D7-2 | 5′-GAT TTG TTT CGG CAT TAT TAT GA-3' |
PCR products were subjected to electrophoresis on 2% agarose and visualized under ultraviolet trans-illumination after staining with SYBR® Green. Fragment sizes were visually calculated relative to a standard size (100 bp) molecular weight DNA marker (New England Biolabs GmbH, Frankfurt am Main, Germany). The DNA fragments were grouped into bins if their fragment sizes were within 20 bp intervals.
Statistical analysis
Data were analysed using XLSTAT Version 2019.1.2 [
34]. The Student’s
t-test was used to compare different normally distributed continuous variables. Numerical data not conforming to normal distribution were log-transformed. The multiplicity of infection (MOI) was defined as the minimum number of parasite genotypes per infected individual and was calculated as the mean number of PCR fragments or parasite genotypes per infected child. Clonality of infection was defined as the number of distinct PCR fragments per infected child. An infection was defined as polyclonal if more than one distinct PCR fragments or parasite genotypes were present in an isolate. Statistical significance was defined as
p < 0.05.
Discussion
The genetic diversity and complexity of
P. falciparum infections is, to a very large extent, an important indicator of malaria transmission intensity in a region and is a very useful marker for assessing naturally acquired anti-malarial immunity as well as the impact of intervention programmes [
9,
35‐
38]. Numerous studies from different regions have devoted efforts at characterizing the genetic complexity of
P. falciparum infections at the community level, but very little attention has been given to studying genetic diversity at the level of the micro-environment. In this study, the genetic diversity and complexities of
P. falciparum infections in the micro-environment was investigated among siblings of the same household. This is the first study to provide information on the genetic diversity and complexity of
P. falciparum infection at the level of the micro-environment in Nigeria, and it will certainly be a great addition to the limited data available on the subject globally.
The results showed that
P. falciparum isolates exhibit a remarkable degree of genetic diversity in the micro-environment. Interestingly, it was found that the pattern of distribution of parasite populations within households may be categorized into two based on the prevalence of
msp-2 allelic families. The first category were households where both
msp-2 allele types (FC27 and 3D7) were present, while the second were households where only one
MSP-2 allele type (FC27 or 3D7) was present. The majority of the households (88.4%) investigated belonged to the first category where both
msp-2 alleles were present, showing that parasite clones carrying FC27 and 3D7 alleles are widely distributed in the study region. This observation was in agreement with a previous study in Tanzania where most of the households investigated had parasites of mixed genotypes [
39]. An important observation in the households where both
msp-2 allelic families were prevalent was that the FC27 and 3D7 alleles were disproportionately distributed among the infected children. Thus, in some households, all the infected children had mixed allelic infections with parasites carrying both FC27 and 3D7 alleles. In contrast, in other households, one of the children had parasite isolates carrying a particular type of
msp-2 allele and the other child had parasite isolates carrying the other type of
msp-2 allele. Nevertheless, in some other households, one or two of the children may be infected with multiple parasite clones or genotypes which may belong to either of the
msp-2 alleles or both. Although about 65% of the households have at least one child with isolates carrying both the FC27 and the 3D7 allele types, only a few households (30.2%) were observed to have all the children carrying isolates belonging to both the FC27 and the 3D7 allelic families. In a previous study in Gabon, it was observed that about 80% of the members of the household investigated had parasite isolates carrying both FC27 and 3D7 alleles [
40] although the study examined only one household. The observed high prevalence of
msp-2 multiclonal infection in this study could be an indication of a high ongoing parasite transmission, suggestive of effective genetic recombination of the parasite population within the female
Anopheles [
41,
42]. Alternatively, it could also have resulted from multiple but independent inoculations of single parasite clones, leading to superinfection. Superinfection is a commonly observed phenomenom in areas of high transmission intensity, especially among individuals with chronic or asymptomatic infections [
43], although young children who are yet to acquire immunity, are thought to be protected from superinfection [
44].
It was also interesting to note that a few households (11.6%) belonged to the second category, where all the children had parasites carrying only one
msp-2 allele type (FC27 or 3D7). This was also consistent with the findings from Tanzania, where they observed a few instances in which different people in the same household had parasites of similar genotypes [
39]. Apart from carrying isolates of the same allele, there were instances also, where identical genotypes or clones (identical fragment sizes) of the same allele were found in all the children in a household. Such infections with parasites of similar genotypes within households might possibly suggest inoculation by a single or related mosquito.
Majority of the participants in this study were infected with a mixture of more than one parasite clone. On the whole, it was found that about 65% of the study participants had polyclonal infections consisting of 2–6 clones with an overall MOI of 2.31 clones per infected child. This observation is consistent with previous reports from Nigeria [
10,
31,
42] and from other parts of Africa [
14,
24,
45‐
52]. The simultaneous infection of large number of individuals with multiple parasite genotypes in areas of high transmission intensity has been suggested to be attributable to either multiple inoculations of single clones, or by a single inoculation of multiple clones that may have undergone crossing and recombination in the female
Anopheles [
52,
54]. Recombination events during the sexual stage of the malaria parasites in the
Anopheles can lead to independent chromosomal re-assortment of genes and is the principal mechanism for generating novel combination of genes, and consequently, new parasite strains with novel genotypes [
52‐
56]. However, diversity may also result from the extensive ectopic recombination events observed during asexual mitotic replication [
57]. Nevertheless, there are indications that high genetic diversity in the parasite population might lead to a gradual selection of more virulent strains which in turn can lead to the emergence and proliferation of drug-resistant parasites [
10,
58,
59].
The present study has some limitations, including: i) the use of a single genetic marker; and, ii) the fact that PCR may not be able to resolve between alleles of similar size but different sequences or those with a size difference of about 10 bp. All of these may potentially underestimate the complexity of infections in this study. However, these data have provided more insight into the genetic complexity of P. falciparum in the micro-environment. Future studies will need to take cognisance of the above limitations, use more robust techniques, and consider other regions with different malaria transmission intensity.
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