Project description:BackgroundHuman immunodeficiency virus (HIV) infection is a global health burden which ultimately results in acquired immune deficiency syndrome (AIDS). There are multiple host factors which are capable of limiting HIV-1 replication. One of the most important host factors which inhibit HIV-1 DNA synthesis is the apolipoprotein B mRNA-editing enzyme, catalytic polypeptide- like 3G (APOBEC3G). Any genetic variation of this important host factor may influence the host susceptibility to viral infection.ObjectiveThe aim of the current study was to evaluate any correlation of APOBEC3G genetic variation rs8177832 with HIV-1 infection.MethodsThe study involved 142 healthy control and 100 HIV-1 infected subjects. The genetic variation rs8177832 of all studied subjects was determined by allele-specific polymerase chain reaction (AS-PCR).ResultsThe results showed that the distribution of rs8177832 genotypes AA, AG and GG in healthy subjects and HIV-1 subjects was; 42.253%, 42.957%, 14.788% and 66%, 27%, 7% respectively. Statistical analyses of data showed that there was a significant variation in rs8177832 genotype AA in healthy control and HIV-1 infected subjects (42.257% vs 66%; p-value<0.001).ConclusionThus it was concluded that APOBEC3G rs8177832 AA genotype contributes in genetic predisposition to HIV-1 infection in Pakistani population.

Project description:The accessory protein Vpx is encoded by lentiviruses of the human immunodeficiency virus type 2 (HIV-2) and the simian immunodeficiency SIVsm/SIVmac lineage. It is packaged into virions and is indispensable in early steps of monocyte infection. HIV-1, which does not encode Vpx, is not able to infect human monocytes, but Vpx enables infection with HIV-1. The underlying mechanism is not completely understood. In this work, we focus on Vpx-mediated intracellular postentry events as counteraction of host cell proteins. We found that Vpx binds to apolipoprotein B mRNA-editing catalytic polypeptide 3 family member A (APOBEC3A; A3A), a member of the family of cytidine deaminases, present in monocytes. This interaction led to a reduction of the steady-state protein level of A3A. A single-point mutation in Vpx (H82A) abrogated binding to A3A and single-round infection of monocytes by HIV-1. Taken together, our data indicate that lentiviral Vpx counteracts A3A in human monocytes.

Project description:Editing of adenosine (A) to inosine (I) at the first anticodon position in tRNA is catalyzed by adenosine deaminases acting on tRNA (ADATs). This essential reaction in bacteria and eukarya permits a single tRNA to decode multiple codons. Bacterial ADATa is a homodimer with two bound essential Zn(2+). The ADATa crystal structure revealed residues important for substrate binding and catalysis; however, such high resolution structural information is not available for eukaryotic tRNA deaminases. Despite significant sequence similarity among deaminases, we continue to uncover unexpected functional differences between Trypanosoma brucei ADAT2/3 (TbADAT2/3) and its bacterial counterpart. Previously, we demonstrated that TbADAT2/3 is unique in catalyzing two different deamination reactions. Here we show by kinetic analyses and inductively coupled plasma emission spectrometry that wild type TbADAT2/3 coordinates two Zn(2+) per heterodimer, but unlike any other tRNA deaminase, mutation of one of the key Zn(2+)-coordinating cysteines in TbADAT2 yields a functional enzyme with a single-bound zinc. These data suggest that, at least, TbADAT3 may play a role in catalysis via direct coordination of the catalytic Zn(2+). These observations raise the possibility of an unusual Zn(2+) coordination interface with important implications for the function and evolution of editing deaminases.

Project description:The AID (activation induced deaminase)/APOBEC (apolipoprotein B mRNA editing catalytic polypeptide-like) family of proteins are zinc-dependent cytidine deaminases active on polynucleotides and involved in RNA editing, DNA demethylation or DNA editing. The enzymatic activity, substrate or physiological target(s) of APOBEC2, a member of the AID/APOBEC, remain elusive. Here, we combined next generation sequencing (NGS) techniques with state-of-the-art molecular biology to comprehensively examine the physiological effects of APOBEC2 on the transcriptome and methylome using C2C12 myoblasts differentiating in culture. We also examined APOBEC2’s genome wide-binding specificity. Using RNA sequencing (RNA-seq) by polyA capture, we detected no evidence that APOBEC2 is an RNA editor. In the same system, enhanced reduced representation bisulfite sequencing (eRRBS) data did not support the proposed role of APOBEC2 as a 5-methyl-C (5mC) deaminase. However, chromatin immunoprecipitation sequencing (ChIP-Seq) did reveal specific locations of genomic occupancy of APOBEC2 with a specific motif preference. Combining biochemical, ChIP-Seq and RNA-Seq gene expression analyses we demonstrate that APOBEC2 acts as a negative regulator of gene expression in muscle cells. Our data support a model of APOBEC2 acting as a chromatin-binding factor that leads to inhibition of transcription of genes involved in cell cycle regulation during C2C12 differentiation. This SuperSeries is composed of the SubSeries listed below.

Project description:PurposeApolipoprotein B mRNA-Editing Catalytic Polypeptide-like (APOBEC) enzymes are mutagenic factors contributing to tumor progression and therapy resistance. However, the effects of APOBEC-induced protein changes have not been systematically assessed. Here, we describe the effects of APOBEC on the coding sequence in primary and metastatic estrogen receptor-positive (ER+)/human epidermal growth factor receptor 2-negative (HER2-) breast cancer (BC).MethodsWe determined the enrichment of amino acid (AA) changes resulting from APOBEC mutagenesis in 323 primary BC tumors and 424 metastatic breast cancer (mBC) lesions via comparison with a simulated mutational genomic landscape not under selection pressure. We subsequently explored genes with recurrent APOBEC-associated AA changes and investigated the clonality of individual APOBEC-associated mutations. Using public sequencing data from an independent primary BC and mBC cohort, we further confirm our findings by reporting genes having these enriched AA changes in an APOBEC context.ResultsOur analysis demonstrated that several APOBEC-derived AA changes are significantly enriched compared with a simulated AA change distribution drawn at random. Among the enriched AA changes, Glutamate(E)>Lysine(K) and Glutamate(E)>Glutamine(Q) were mostly found at hotspots in oncogenes, whereas termination codons (Glutamine[Q]>STOP[X] and Serine[S]>STOP[X]) occurred in tumor suppressor genes and, mostly, not at hotspot locations. These mutations are found in genes contributing to BC initiation, eg, introduction of termination codons in TP53, MAP3K1, and CDH1 (in lobular BC) and two oncogenic hotspots in PIK3CA (p.E542K and p.E545K). In endocrine-resistant BC, we observed APOBEC-induced termination codons at ER-modulating genes, KMT2C, ARID1A, NF1, and ZFHX3. Finally, in mBC, compared with single PIK3CA mutations, dual PIK3CA mutations occurred more frequently in an APOBEC context (Fisher's exact P < .001).ConclusionOur results show that APOBEC mutagenesis recurrently targets various known drivers of BC initiation, progression, and endocrine resistance.

Project description:Ocular delivery of lipid nanoparticle (LNPs) packaged mRNA can enable efficient gene delivery and editing. We generated LNP variants through the inclusion of positively charged-amine-modified polyethylene glycol (PEG)-lipids (LNPa), negatively charged-carboxyl-(LNPz) and carboxy-ester (LNPx) modified PEG-lipids, and neutral unmodified PEG-lipids (LNP). Subretinal injections of LNPa containing Cre mRNA in the mouse show tdTomato signal in the retinal pigmented epithelium (RPE) like conventional LNPs. Unexpectedly, LNPx and LNPz show 27% and 16% photoreceptor transfection, respectively, with striking localization extending from the photoreceptor synaptic pedicle to the outer segments, displaying pan-retinal distribution in the photoreceptors and RPE. LNPx containing Cas9 mRNA and sgAi9 leads to the formation of an oval elongated structure with a neutral charge resulting in 16.4% editing restricted to RPE. Surface modifications of LNPs with PEG variants can alter cellular tropism of mRNA. LNPs enable genome editing in the retina and in the future can be used to correct genetic mutations that lead to blindness.

Project description:The AID (activation induced deaminase)/APOBEC (apolipoprotein B mRNA editing catalytic polypeptide-like) family of proteins are zinc-dependent cytidine deaminases active on polynucleotides and involved in RNA editing, DNA demethylation or DNA editing. The enzymatic activity, substrate or physiological target(s) of APOBEC2, a member of the AID/APOBEC, remain elusive. Here, we combined next generation sequencing (NGS) techniques with state-of-the-art molecular biology to comprehensively examine the physiological effects of APOBEC2 on the transcriptome and methylome using C2C12 myoblasts differentiating in culture. We also examined APOBEC2’s genome wide-binding specificity. Using RNA sequencing (RNA-seq) by polyA capture, we detected no evidence that APOBEC2 is an RNA editor. In the same system, enhanced reduced representation bisulfite sequencing (eRRBS) data did not support the proposed role of APOBEC2 as a 5-methyl-C (5mC) deaminase. However, chromatin immunoprecipitation sequencing (ChIP-Seq) did reveal specific locations of genomic occupancy of APOBEC2 with a specific motif preference. Combining biochemical, ChIP-Seq and RNA-Seq gene expression analyses we demonstrate that APOBEC2 acts as a negative regulator of gene expression in muscle cells. Our data support a model of APOBEC2 acting as a chromatin-binding factor that leads to inhibition of transcription of genes involved in cell cycle regulation during C2C12 differentiation.

Project description:DesignPromiscuous guanine (G) to adenine (A) substitutions catalysed by apolipoprotein B RNA-editing catalytic component (APOBEC) enzymes are observed in a proportion of HIV-1 sequences in vivo and can introduce artifacts into some genetic analyses. The potential impact of undetected lethal editing on genotypic estimation of transmitted drug resistance was assessed.MethodsClassifiers of lethal, APOBEC-mediated editing were developed by analysis of lentiviral pol gene sequence variation and evaluated using control sets of HIV-1 sequences. The potential impact of sequence editing on genotypic estimation of drug resistance was assessed in sets of sequences obtained from 77 studies of 25 or more therapy-naive individuals, using mixture modelling approaches to determine the maximum likelihood classification of sequences as lethally edited as opposed to viable.ResultsAnalysis of 6437 protease and reverse transcriptase sequences from therapy-naive individuals using a novel classifier of lethal, APOBEC3G-mediated sequence editing, the polypeptide-like 3G (APOBEC3G)-mediated defectives (A3GD) index', detected lethal editing in association with spurious 'transmitted drug resistance' in nearly 3% of proviral sequences obtained from whole blood and 0.2% of samples obtained from plasma.ConclusionScreening for lethally edited sequences in datasets containing a proportion of proviral DNA, such as those likely to be obtained for epidemiological surveillance of transmitted drug resistance in the developing world, can eliminate rare but potentially significant errors in genotypic estimation of transmitted drug resistance.

Project description:The AID (activation induced deaminase)/APOBEC (apolipoprotein B mRNA editing catalytic polypeptide-like) family of proteins are zinc-dependent cytidine deaminases active on polynucleotides and involved in RNA editing, DNA demethylation or DNA editing. The enzymatic activity, substrate or physiological target(s) of APOBEC2, a member of the AID/APOBEC, remain elusive. Here, we combined next generation sequencing (NGS) techniques with state-of-the-art molecular biology to comprehensively examine the physiological effects of APOBEC2 on the transcriptome and methylome using C2C12 myoblasts differentiating in culture. We also examined APOBEC2’s genome wide-binding specificity. Using RNA sequencing (RNA-seq) by polyA capture, we detected no evidence that APOBEC2 is an RNA editor. In the same system, enhanced reduced representation bisulfite sequencing (eRRBS) data did not support the proposed role of APOBEC2 as a 5-methyl-C (5mC) deaminase. However, chromatin immunoprecipitation sequencing (ChIP-Seq) did reveal specific locations of genomic occupancy of APOBEC2 with a specific motif preference. Combining biochemical, ChIP-Seq and RNA-Seq gene expression analyses we demonstrate that APOBEC2 acts as a negative regulator of gene expression in muscle cells. Our data support a model of APOBEC2 acting as a chromatin-binding factor that leads to inhibition of transcription of genes involved in cell cycle regulation during C2C12 differentiation.

Project description:The AID (activation induced deaminase)/APOBEC (apolipoprotein B mRNA editing catalytic polypeptide-like) family of proteins are zinc-dependent cytidine deaminases active on polynucleotides and involved in RNA editing, DNA demethylation or DNA editing. The enzymatic activity, substrate or physiological target(s) of APOBEC2, a member of the AID/APOBEC, remain elusive. Here, we combined next generation sequencing (NGS) techniques with state-of-the-art molecular biology to comprehensively examine the physiological effects of APOBEC2 on the transcriptome and methylome using C2C12 myoblasts differentiating in culture. We also examined APOBEC2’s genome wide-binding specificity. Using RNA sequencing (RNA-seq) by polyA capture, we detected no evidence that APOBEC2 is an RNA editor. In the same system, enhanced reduced representation bisulfite sequencing (eRRBS) data did not support the proposed role of APOBEC2 as a 5-methyl-C (5mC) deaminase. However, chromatin immunoprecipitation sequencing (ChIP-Seq) did reveal specific locations of genomic occupancy of APOBEC2 with a specific motif preference. Combining biochemical, ChIP-Seq and RNA-Seq gene expression analyses we demonstrate that APOBEC2 acts as a negative regulator of gene expression in muscle cells. Our data support a model of APOBEC2 acting as a chromatin-binding factor that leads to inhibition of transcription of genes involved in cell cycle regulation during C2C12 differentiation.