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Dive into the research topics where Sakina Saif is active.

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Featured researches published by Sakina Saif.


Nature Genetics | 2012

The malaria parasite Plasmodium vivax exhibits greater genetic diversity than Plasmodium falciparum

Daniel E. Neafsey; Kevin Galinsky; Rays H. Y. Jiang; Lauren Young; Sean Sykes; Sakina Saif; Sharvari Gujja; Jonathan M. Goldberg; Qiandong Zeng; Sinéad B. Chapman; A. P. Dash; Anupkumar R. Anvikar; Patrick L. Sutton; Bruce W. Birren; Ananias A. Escalante; John W. Barnwell; Jane M. Carlton

We sequenced and annotated the genomes of four P. vivax strains collected from disparate geographic locations, tripling the number of genome sequences available for this understudied parasite and providing the first genome-wide perspective of global variability in this species. We observe approximately twice as much SNP diversity among these isolates as we do among a comparable collection of isolates of P. falciparum, a malaria-causing parasite that results in higher mortality. This indicates a distinct history of global colonization and/or a more stable demographic history for P. vivax relative to P. falciparum, which is thought to have undergone a recent population bottleneck. The SNP diversity, as well as additional microsatellite and gene family variability, suggests a capacity for greater functional variation in the global population of P. vivax. These findings warrant a deeper survey of variation in P. vivax to equip disease interventions targeting the distinctive biology of this neglected but major pathogen.


Mbio | 2013

Emergence of Epidemic Multidrug-Resistant Enterococcus faecium from Animal and Commensal Strains

François Lebreton; Willem van Schaik; Abigail Manson McGuire; Paul A. Godfrey; Allison D. Griggs; Varun Mazumdar; Jukka Corander; Lu Cheng; Sakina Saif; Qiandong Zeng; Jennifer R. Wortman; Bruce W. Birren; Rob J. L. Willems; Ashlee M. Earl; Michael S. Gilmore

ABSTRACT Enterococcus faecium, natively a gut commensal organism, emerged as a leading cause of multidrug-resistant hospital-acquired infection in the 1980s. As the living record of its adaptation to changes in habitat, we sequenced the genomes of 51 strains, isolated from various ecological environments, to understand how E. faecium emerged as a leading hospital pathogen. Because of the scale and diversity of the sampled strains, we were able to resolve the lineage responsible for epidemic, multidrug-resistant human infection from other strains and to measure the evolutionary distances between groups. We found that the epidemic hospital-adapted lineage is rapidly evolving and emerged approximately 75 years ago, concomitant with the introduction of antibiotics, from a population that included the majority of animal strains, and not from human commensal lines. We further found that the lineage that included most strains of animal origin diverged from the main human commensal line approximately 3,000 years ago, a time that corresponds to increasing urbanization of humans, development of hygienic practices, and domestication of animals, which we speculate contributed to their ecological separation. Each bifurcation was accompanied by the acquisition of new metabolic capabilities and colonization traits on mobile elements and the loss of function and genome remodeling associated with mobile element insertion and movement. As a result, diversity within the species, in terms of sequence divergence as well as gene content, spans a range usually associated with speciation. IMPORTANCE Enterococci, in particular vancomycin-resistant Enterococcus faecium, recently emerged as a leading cause of hospital-acquired infection worldwide. In this study, we examined genome sequence data to understand the bacterial adaptations that accompanied this transformation from microbes that existed for eons as members of host microbiota. We observed changes in the genomes that paralleled changes in human behavior. An initial bifurcation within the species appears to have occurred at a time that corresponds to the urbanization of humans and domestication of animals, and a more recent bifurcation parallels the introduction of antibiotics in medicine and agriculture. In response to the opportunity to fill niches associated with changes in human activity, a rapidly evolving lineage emerged, a lineage responsible for the vast majority of multidrug-resistant E. faecium infections. Enterococci, in particular vancomycin-resistant Enterococcus faecium, recently emerged as a leading cause of hospital-acquired infection worldwide. In this study, we examined genome sequence data to understand the bacterial adaptations that accompanied this transformation from microbes that existed for eons as members of host microbiota. We observed changes in the genomes that paralleled changes in human behavior. An initial bifurcation within the species appears to have occurred at a time that corresponds to the urbanization of humans and domestication of animals, and a more recent bifurcation parallels the introduction of antibiotics in medicine and agriculture. In response to the opportunity to fill niches associated with changes in human activity, a rapidly evolving lineage emerged, a lineage responsible for the vast majority of multidrug-resistant E. faecium infections.


Nature Genetics | 2013

Genomics of Loa loa, a Wolbachia-free filarial parasite of humans.

Christopher A. Desjardins; Gustavo C. Cerqueira; Jonathan M. Goldberg; Julie C. Dunning Hotopp; Brian J. Haas; Jeremy Zucker; José M. C. Ribeiro; Sakina Saif; Joshua Z. Levin; Lin Fan; Qiandong Zeng; Carsten Russ; Jennifer R. Wortman; Doran L. Fink; Bruce Birren; Thomas B. Nutman

Loa loa, the African eyeworm, is a major filarial pathogen of humans. Unlike most filariae, L. loa does not contain the obligate intracellular Wolbachia endosymbiont. We describe the 91.4-Mb genome of L. loa and that of the related filarial parasite Wuchereria bancrofti and predict 14,907 L. loa genes on the basis of microfilarial RNA sequencing. By comparing these genomes to that of another filarial parasite, Brugia malayi, and to those of several other nematodes, we demonstrate synteny among filariae but not with nonparasitic nematodes. The L. loa genome encodes many immunologically relevant genes, as well as protein kinases targeted by drugs currently approved for use in humans. Despite lacking Wolbachia, L. loa shows no new metabolic synthesis or transport capabilities compared to other filariae. These results suggest that the role of Wolbachia in filarial biology is more subtle than previously thought and reveal marked differences between parasitic and nonparasitic nematodes.


Mbio | 2012

Comparative Genome Analysis of Trichophyton rubrum and Related Dermatophytes Reveals Candidate Genes Involved in Infection

Diego Martinez; Brian G. Oliver; Yvonne Gräser; Jonathan M. Goldberg; Wenjun Li; Nilce M. Martinez-Rossi; Michel Monod; Ekaterina Shelest; Richard Barton; Elizabeth Birch; Axel A. Brakhage; Zehua Chen; Sarah J. Gurr; David I. Heiman; Joseph Heitman; Idit Kosti; Antonio Rossi; Sakina Saif; Marketa Samalova; Charles Winston Saunders; Terrance Shea; Richard C. Summerbell; Jun Xu; Qiandong Zeng; Bruce W. Birren; Christina A. Cuomo; Theodore C. White

ABSTRACT The major cause of athlete’s foot is Trichophyton rubrum, a dermatophyte or fungal pathogen of human skin. To facilitate molecular analyses of the dermatophytes, we sequenced T. rubrum and four related species, Trichophyton tonsurans, Trichophyton equinum, Microsporum canis, and Microsporum gypseum. These species differ in host range, mating, and disease progression. The dermatophyte genomes are highly colinear yet contain gene family expansions not found in other human-associated fungi. Dermatophyte genomes are enriched for gene families containing the LysM domain, which binds chitin and potentially related carbohydrates. These LysM domains differ in sequence from those in other species in regions of the peptide that could affect substrate binding. The dermatophytes also encode novel sets of fungus-specific kinases with unknown specificity, including nonfunctional pseudokinases, which may inhibit phosphorylation by competing for kinase sites within substrates, acting as allosteric effectors, or acting as scaffolds for signaling. The dermatophytes are also enriched for a large number of enzymes that synthesize secondary metabolites, including dermatophyte-specific genes that could synthesize novel compounds. Finally, dermatophytes are enriched in several classes of proteases that are necessary for fungal growth and nutrient acquisition on keratinized tissues. Despite differences in mating ability, genes involved in mating and meiosis are conserved across species, suggesting the possibility of cryptic mating in species where it has not been previously detected. These genome analyses identify gene families that are important to our understanding of how dermatophytes cause chronic infections, how they interact with epithelial cells, and how they respond to the host immune response. IMPORTANCE Athlete’s foot, jock itch, ringworm, and nail infections are common fungal infections, all caused by fungi known as dermatophytes (fungi that infect skin). This report presents the genome sequences of Trichophyton rubrum, the most frequent cause of athlete’s foot, as well as four other common dermatophytes. Dermatophyte genomes are enriched for four gene classes that may contribute to the ability of these fungi to cause disease. These include (i) proteases secreted to degrade skin; (ii) kinases, including pseudokinases, that are involved in signaling necessary for adapting to skin; (iii) secondary metabolites, compounds that act as toxins or signals in the interactions between fungus and host; and (iv) a class of proteins (LysM) that appear to bind and mask cell wall components and carbohydrates, thus avoiding the host’s immune response to the fungi. These genome sequences provide a strong foundation for future work in understanding how dermatophytes cause disease. Athlete’s foot, jock itch, ringworm, and nail infections are common fungal infections, all caused by fungi known as dermatophytes (fungi that infect skin). This report presents the genome sequences of Trichophyton rubrum, the most frequent cause of athlete’s foot, as well as four other common dermatophytes. Dermatophyte genomes are enriched for four gene classes that may contribute to the ability of these fungi to cause disease. These include (i) proteases secreted to degrade skin; (ii) kinases, including pseudokinases, that are involved in signaling necessary for adapting to skin; (iii) secondary metabolites, compounds that act as toxins or signals in the interactions between fungus and host; and (iv) a class of proteins (LysM) that appear to bind and mask cell wall components and carbohydrates, thus avoiding the host’s immune response to the fungi. These genome sequences provide a strong foundation for future work in understanding how dermatophytes cause disease.


Journal of Clinical Investigation | 2010

Wilms tumor 1 (WT1) regulates KRAS-driven oncogenesis and senescence in mouse and human models

Silvestre Vicent; Ron Chen; Leanne C. Sayles; Chenwei Lin; Randal G. Walker; Anna K. Gillespie; Aravind Subramanian; Gregory Hinkle; Xiaoping Yang; Sakina Saif; David E. Root; Vicki Huff; William C. Hahn; E. Alejandro Sweet-Cordero

KRAS is one of the most frequently mutated human oncogenes. In some settings, oncogenic KRAS can trigger cellular senescence, whereas in others it produces hyperproliferation. Elucidating the mechanisms regulating these 2 drastically distinct outcomes would help identify novel therapeutic approaches in RAS-driven cancers. Using a combination of functional genomics and mouse genetics, we identified a role for the transcription factor Wilms tumor 1 (WT1) as a critical regulator of senescence and proliferation downstream of oncogenic KRAS signaling. Deletion or suppression of Wt1 led to senescence of mouse primary cells expressing physiological levels of oncogenic Kras but had no effect on wild-type cells, and Wt1 loss decreased tumor burden in a mouse model of Kras-driven lung cancer. In human lung cancer cell lines dependent on oncogenic KRAS, WT1 loss decreased proliferation and induced senescence. Furthermore, WT1 inactivation defined a gene expression signature that was prognostic of survival only in lung cancer patients exhibiting evidence of oncogenic KRAS activation. These findings reveal an unexpected role for WT1 as a key regulator of the genetic network of oncogenic KRAS and provide important insight into the mechanisms that regulate proliferation or senescence in response to oncogenic signals.


PLOS ONE | 2010

Analysis of high-throughput sequencing and annotation strategies for phage genomes

Matthew R. Henn; Matthew B. Sullivan; Nicole Stange-Thomann; Marcia S. Osburne; Aaron M. Berlin; Libusha Kelly; Chandri Yandava; Chinnappa D. Kodira; Qiandong Zeng; Michael Weiand; Todd Sparrow; Sakina Saif; Georgia Giannoukos; Sarah K. Young; Chad Nusbaum; Bruce W. Birren; Sallie W. Chisholm

Background Bacterial viruses (phages) play a critical role in shaping microbial populations as they influence both host mortality and horizontal gene transfer. As such, they have a significant impact on local and global ecosystem function and human health. Despite their importance, little is known about the genomic diversity harbored in phages, as methods to capture complete phage genomes have been hampered by the lack of knowledge about the target genomes, and difficulties in generating sufficient quantities of genomic DNA for sequencing. Of the approximately 550 phage genomes currently available in the public domain, fewer than 5% are marine phage. Methodology/Principal Findings To advance the study of phage biology through comparative genomic approaches we used marine cyanophage as a model system. We compared DNA preparation methodologies (DNA extraction directly from either phage lysates or CsCl purified phage particles), and sequencing strategies that utilize either Sanger sequencing of a linker amplification shotgun library (LASL) or of a whole genome shotgun library (WGSL), or 454 pyrosequencing methods. We demonstrate that genomic DNA sample preparation directly from a phage lysate, combined with 454 pyrosequencing, is best suited for phage genome sequencing at scale, as this method is capable of capturing complete continuous genomes with high accuracy. In addition, we describe an automated annotation informatics pipeline that delivers high-quality annotation and yields few false positives and negatives in ORF calling. Conclusions/Significance These DNA preparation, sequencing and annotation strategies enable a high-throughput approach to the burgeoning field of phage genomics.


Mbio | 2015

Genome Evolution and Innovation across the Four Major Lineages of Cryptococcus gattii

Rhys A. Farrer; Christopher A. Desjardins; Sharadha Sakthikumar; Sharvari Gujja; Sakina Saif; Qiandong Zeng; Yuan Chen; Kerstin Voelz; Joseph Heitman; Robin C. May; Matthew C. Fisher; Christina A. Cuomo

ABSTRACT Cryptococcus gattii is a fungal pathogen of humans, causing pulmonary infections in otherwise healthy hosts. To characterize genomic variation among the four major lineages of C. gattii (VGI, -II, -III, and -IV), we generated, annotated, and compared 16 de novo genome assemblies, including the first for the rarely isolated lineages VGIII and VGIV. By identifying syntenic regions across assemblies, we found 15 structural rearrangements, which were almost exclusive to the VGI-III-IV lineages. Using synteny to inform orthology prediction, we identified a core set of 87% of C. gattii genes present as single copies in all four lineages. Remarkably, 737 genes are variably inherited across lineages and are overrepresented for response to oxidative stress, mitochondrial import, and metal binding and transport. Specifically, VGI has an expanded set of iron-binding genes thought to be important to the virulence of Cryptococcus, while VGII has expansions in the stress-related heat shock proteins relative to the other lineages. We also characterized genes uniquely absent in each lineage, including a copper transporter absent from VGIV, which influences Cryptococcus survival during pulmonary infection and the onset of meningoencephalitis. Through inclusion of population-level data for an additional 37 isolates, we identified a new transcontinental clonal group that we name VGIIx, mitochondrial recombination between VGII and VGIII, and positive selection of multidrug transporters and the iron-sulfur protein aconitase along multiple branches of the phylogenetic tree. Our results suggest that gene expansion or contraction and positive selection have introduced substantial variation with links to mechanisms of pathogenicity across this species complex. IMPORTANCE The genetic differences between phenotypically different pathogens provide clues to the underlying mechanisms of those traits and can lead to new drug targets and improved treatments for those diseases. In this paper, we compare 16 genomes belonging to four highly differentiated lineages of Cryptococcus gattii, which cause pulmonary infections in otherwise healthy humans and other animals. Half of these lineages have not had their genomes previously assembled and annotated. We identified 15 ancestral rearrangements in the genome and over 700 genes that are unique to one or more lineages, many of which are associated with virulence. In addition, we found evidence for recent transcontinental spread, mitochondrial genetic exchange, and positive selection in multidrug transporters. Our results suggest that gene expansion/contraction and positive selection are diversifying the mechanisms of pathogenicity across this species complex. The genetic differences between phenotypically different pathogens provide clues to the underlying mechanisms of those traits and can lead to new drug targets and improved treatments for those diseases. In this paper, we compare 16 genomes belonging to four highly differentiated lineages of Cryptococcus gattii, which cause pulmonary infections in otherwise healthy humans and other animals. Half of these lineages have not had their genomes previously assembled and annotated. We identified 15 ancestral rearrangements in the genome and over 700 genes that are unique to one or more lineages, many of which are associated with virulence. In addition, we found evidence for recent transcontinental spread, mitochondrial genetic exchange, and positive selection in multidrug transporters. Our results suggest that gene expansion/contraction and positive selection are diversifying the mechanisms of pathogenicity across this species complex.


PLOS Genetics | 2015

The dynamic genome and transcriptome of the human fungal pathogen Blastomyces and close relative Emmonsia

Jose F. Muñoz; Gregory M. Gauthier; Christopher A. Desjardins; Juan Esteban Gallo; Jason Holder; Thomas D. Sullivan; Amber J. Marty; John C. Carmen; Zehua Chen; Li Ding; Sharvari Gujja; Vincent Magrini; Elizabeth Misas; Makedonka Mitreva; Margaret Priest; Sakina Saif; Emily Whiston; Qiandong Zeng; William E. Goldman; Elaine R. Mardis; John W. Taylor; Juan G. McEwen; Oliver K. Clay; Bruce S. Klein; Christina A. Cuomo

Three closely related thermally dimorphic pathogens are causal agents of major fungal diseases affecting humans in the Americas: blastomycosis, histoplasmosis and paracoccidioidomycosis. Here we report the genome sequence and analysis of four strains of the etiological agent of blastomycosis, Blastomyces, and two species of the related genus Emmonsia, typically pathogens of small mammals. Compared to related species, Blastomyces genomes are highly expanded, with long, often sharply demarcated tracts of low GC-content sequence. These GC-poor isochore-like regions are enriched for gypsy elements, are variable in total size between isolates, and are least expanded in the avirulent B. dermatitidis strain ER-3 as compared with the virulent B. gilchristii strain SLH14081. The lack of similar regions in related species suggests these isochore-like regions originated recently in the ancestor of the Blastomyces lineage. While gene content is highly conserved between Blastomyces and related fungi, we identified changes in copy number of genes potentially involved in host interaction, including proteases and characterized antigens. In addition, we studied gene expression changes of B. dermatitidis during the interaction of the infectious yeast form with macrophages and in a mouse model. Both experiments highlight a strong antioxidant defense response in Blastomyces, and upregulation of dioxygenases in vivo suggests that dioxide produced by antioxidants may be further utilized for amino acid metabolism. We identify a number of functional categories upregulated exclusively in vivo, such as secreted proteins, zinc acquisition proteins, and cysteine and tryptophan metabolism, which may include critical virulence factors missed before in in vitro studies. Across the dimorphic fungi, loss of certain zinc acquisition genes and differences in amino acid metabolism suggest unique adaptations of Blastomyces to its host environment. These results reveal the dynamics of genome evolution and of factors contributing to virulence in Blastomyces.


Journal of Virology | 2015

Genome Sequencing and Analysis of Geographically Diverse Clinical Isolates of Herpes Simplex Virus 2

Ruchi M. Newman; Susanna L. Lamers; Brian Weiner; Stuart C. Ray; Robert C. Colgrove; Fernando Diaz; Lichen Jing; Kening Wang; Sakina Saif; Matthew R. Henn; Oliver Laeyendecker; Aaron A. R. Tobian; Jeffrey I. Cohen; David M. Koelle; Thomas C. Quinn; David M. Knipe

ABSTRACT Herpes simplex virus 2 (HSV-2), the principal causative agent of recurrent genital herpes, is a highly prevalent viral infection worldwide. Limited information is available on the amount of genomic DNA variation between HSV-2 strains because only two genomes have been determined, the HG52 laboratory strain and the newly sequenced SD90e low-passage-number clinical isolate strain, each from a different geographical area. In this study, we report the nearly complete genome sequences of 34 HSV-2 low-passage-number and laboratory strains, 14 of which were collected in Uganda, 1 in South Africa, 11 in the United States, and 8 in Japan. Our analyses of these genomes demonstrated remarkable sequence conservation, regardless of geographic origin, with the maximum nucleotide divergence between strains being 0.4% across the genome. In contrast, prior studies indicated that HSV-1 genomes exhibit more sequence diversity, as well as geographical clustering. Additionally, unlike HSV-1, little viral recombination between HSV-2 strains could be substantiated. These results are interpreted in light of HSV-2 evolution, epidemiology, and pathogenesis. Finally, the newly generated sequences more closely resemble the low-passage-number SD90e than HG52, supporting the use of the former as the new reference genome of HSV-2. IMPORTANCE Herpes simplex virus 2 (HSV-2) is a causative agent of genital and neonatal herpes. Therefore, knowledge of its DNA genome and genetic variability is central to preventing and treating genital herpes. However, only two full-length HSV-2 genomes have been reported. In this study, we sequenced 34 additional HSV-2 low-passage-number and laboratory viral genomes and initiated analysis of the genetic diversity of HSV-2 strains from around the world. The analysis of these genomes will facilitate research aimed at vaccine development, diagnosis, and the evaluation of clinical manifestations and transmission of HSV-2. This information will also contribute to our understanding of HSV evolution.


Virology | 2014

Genomic sequences of a low passage herpes simplex virus 2 clinical isolate and its plaque-purified derivative strain.

Robert C. Colgrove; Fernando Diaz; Ruchi M. Newman; Sakina Saif; Terry Shea; Matt Henn; David M. Knipe

Herpes simplex virus 2 is an important human pathogen as the causative agent of genital herpes, neonatal herpes, and increased risk of HIV acquisition and transmission. Nevertheless, the only genomic sequence that has been completed is the attenuated HSV-2 HG52 laboratory strain. In this study we defined the genomic sequence of the HSV-2 SD90e low passage clinical isolate and a plaque-purified derivative, SD90-3P. We found minimal sequence differences between SD90e and SD90-3P. However, in comparisons with the HSV-2 HG52 reference genome sequence, the SD90e genome ORFs contained numerous point mutations, 13 insertions/deletions (indels), and 9 short compensatory frameshifts. The indels were true sequence differences, but the compensatory frameshifts were likely sequence errors in the original HG52 sequence. Because HG52 virus is less virulent than other HSV-2 strains and may not be representative of wildtype HSV-2 strains, we propose that the HSV-2 SD90e genome serve as the new HSV-2 reference genome.

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