Clinical characteristics of women with HIV in the RESPOND cohort: A descriptive analysis and comparison to men.

BACKGROUND: Women with HIV are globally underrepresented in clinical research. Existing studies often focus on reproductive outcomes, seldom focus on older women, and are often underpowered to assess sex/gender differences. We describe CD4, HIV viral load (VL), clinical characteristics, comorbidity burden, and use of antiretroviral therapy (ART) among women with HIV in the RESPOND study and compare them with those of the men in RESPOND. METHODS: RESPOND is a prospective, multi-cohort collaboration including over 34 000 people with HIV from across Europe and Australia. Demographic and clinical characteristics, including CD4/VL, comorbidity burden, and ART are presented at baseline, defined as the latter of 1 January 2012 or enrolment into the local cohort, stratified by age and sex/gender. We further stratify men by reported mode of HIV acquisition, men who have sex with men (MSM) and non-MSM. RESULTS: Women account for 26.0% (n = 9019) of the cohort, with a median age of 42.2 years (interquartile range [IQR] 34.7-49.1). The majority (59.3%) of women were white, followed by 30.3% Black. Most women (75.8%) had acquired HIV heterosexually and 15.9% via injecting drug use. Nearly half (44.8%) were receiving a boosted protease inhibitor, 31.4% a non-nucleoside reverse transcriptase inhibitor, and 7.8% an integrase strand transfer inhibitor. The baseline year was 2012 for 73.2% of women and >2019 for 4.2%. Median CD4 was 523 (IQR 350-722) cells/µl, and 73.6% of women had a VL <200 copies/mL. Among the ART-naïve population, women were more likely than MSM but less likely than non-MSM (p < 0.001) to have CD4 <200 cells/µL and less likely than both MSM and non-MSM (p < 0.001) to have VL ≥100 000 copies/mL. Women were also more likely to be free of comorbidity than were both MSM and non-MSM (p < 0.0001). CONCLUSION: RESPOND women are diverse in age, ethnicity/race, CD4/VL, and comorbidity burden, with important differences relative to men. This work highlights the importance of stratification by sex/gender for future research that may help improve screening and management guidelines specifically for women with HIV.

Latent infection of CD4+ T cells provides a mechanism for lifelong persistence of HIV-1, even in patients on effective combination therapy.

Combination therapy for HIV-1 infection can reduce plasma virus to undetectable levels, indicating that prolonged treatment might eradicate the infection. However, HIV-1 can persist in a latent form in resting CD4+ T cells. We measured the decay rate of this latent reservoir in 34 treated adults whose plasma virus levels were undetectable. The mean half-life of the latent reservoir was very long (43.9 months). If the latent reservoir consists of only 1 x 10(5) cells, eradication could take as long as 60 years. Thus, latent infection of resting CD4+ T cells provides a mechanism for lifelong persistence of HIV-1, even in patients on effective anti-retroviral therapy.

Sparse coding and decorrelation in primary visual cortex during natural vision.

Theoretical studies suggest that primary visual cortex (area V1) uses a sparse code to efficiently represent natural scenes. This issue was investigated by recording from V1 neurons in awake behaving macaques during both free viewing of natural scenes and conditions simulating natural vision. Stimulation of the nonclassical receptive field increases the selectivity and sparseness of individual V1 neurons, increases the sparseness of the population response distribution, and strongly decorrelates the responses of neuron pairs. These effects are due to both excitatory and suppressive modulation of the classical receptive field by the nonclassical receptive field and do not depend critically on the spatiotemporal structure of the stimuli. During natural vision, the classical and nonclassical receptive fields function together to form a sparse representation of the visual world. This sparse code may be computationally efficient for both early vision and higher visual processing.

Weight-watching at the university: the consequences of growth.

We began by pointing out that tools (for example) have size optima that are dictated by function. If we assume that the university has a function, it would seem reasonable to think about the size which will serve that function best. The principle of size optimization is fundamental, but its application to the university at once encounters a difficulty: What is the function of a university? It might take forever to secure general agreement on the answer to this question. The problem is that universities have a number of different functions, to which different individuals will attach different weights, and each function may well have a unique size optimum. Just as it is, in general, mathematically impossible to maximize simultaneously for two different functions of the same variable (29), so it is unsound to conceive of a single optimum for the multiversity. Nonetheless, a range of workable sizes may be defined by analyzing the effect of variation in size on all essential functions. The examples from biological systems illustrate this approach. Cells exist in a variety of sizes, each size presumably representing an optimization to one or another set of constraints, yet there are upper bounds. There are no cells the size of basketballs because essential metabolic functions are limited by the surface-to-volume ratio. We must emphasize that one does not need a grand theory of life in order to identify this limiting condition. If cells could talk, they would no doubt differ on the general philosophy of being a cell, yet all conceptions would be subject to certain physically inevitable limitations on size. In the case of the university, no grand theory of education is needed in order to identify dysfunctions of growth that affect essential activities (for example, the diffusion of individuals through, in, and out of the university) or that affect all activities (for example, overall morale). Balanced against these dysfunctions are such advantages of growth as economy, the achievement of a critical mass, and flexibility in staffing. Our analyis of data from the California system indicates that unit costs of education decline very little above a size of 10,000 or 15,000 students. Moreover, the critical mass for departmental excellence, at least in terms of the ACE ratings of graduate departments, is achieved by a university of about this size. Growth beyond this size range conitinues to provide flexibility in staffing and spares administrators the trouble of having to make difficult decisions. At the same time, the dysfunctions attendant on growth become steadily more severe. Our impression is that the dysfunctions have not been seriously considered, while the advantages have been greatly oversold. The idea of dysfunctional growth, although fundamental in biology, contradicts one of America's most cherished illusions. Particular dysfunctions of growth are rarely formulated, set down, and explicitly weighed against the potential advantages. Rather, the American prejudice has been to assume that growth is always good, or at least inevitable, and to treat the dysfunctions (which are inevitable) as managerial problems to be ironed out later or glossed over. There has also been a remarkable failure to think in terms of optima and to distinguish in this way between what we have termed functional and dysfunctional growth. Rather, the tendency has been to extrapolate functional growth into the dysfunctional range: If a university population of 10,000 confers certain advantages as compared with a population of 1,000, then it is assumed that a population of 100,000 must confer even more advantages. We suggest that it is time, in fact past time, to subject university growth to a more searching scrutiny. Functional and dysfunctional consequences need to be spelled out. Scale effects ought to be considered in connection with every plan for expansion. Ideally, one might expect a farsighted and tough-minded administration to carry out this function. This has rarely been the case. Too often administrators regard their function as simply that of broker among competing expansionist tendencies. Such a conception replaces philosophy by politics and often encourages mindless growth. Perhaps it is time for faculties to involve themselves in long-range planning and to pay the price of a more satisfactory environment by giving up some individual dreams of empire. The first step for every large university ought to be a careful analysis of scale effects (30). If analysis indicates that continued growth of a university will be, on balance, dysfunctional, we suggest that plans be formulated to establish an absolute limit on further enrollment increase, and an absolute limit on further building expansion. If further analysis indicates that a university is already well into the dysfunctional size range, then the obvious solution is to cut back. If this turns out to be the case, then we suggest that a program for the gradual reduction of the campus population be undertaken. There are two distinct ways to accomplish this: (i) the establishment of a new university and (ii) the decentralization of the existing university into two or more campuses. Decentralization strikes us as an attractive idea, worthy of careful study. One of the recommendations of the Scranton commission was, "Large universities should take steps to decentralize or reorganize to make possible a more human scale" (18, p. 14). Returning to the natural world, we note again that cells do not grow indefinitely. Instead, they divide.

Selectivity for polar, hyperbolic, and Cartesian gratings in macaque visual cortex.

The neural basis of pattern recognition is a central problem in visual neuroscience. Responses of single cells were recorded in area V4 of macaque monkey to three classes of periodic stimuli that are based on spatial derivative operators: polar (concentric and radial), hyperbolic, and conventional sinusoidal (Cartesian) gratings. Of 118 cells tested, 16 percent responded significantly more to polar or hyperbolic (non-Cartesian) gratings than to Cartesian gratings and only 8 percent showed a significant preference for Cartesian gratings. Among cells selective for non-Cartesian gratings, those that preferred concentric gratings were most common. Cells selective for non-Cartesian gratings may constitute an important intermediate stage in pattern recognition and the representation of surface shape.

Identification of a reservoir for HIV-1 in patients on highly active antiretroviral therapy.

The hypothesis that quiescent CD4+ T lymphocytes carrying proviral DNA provide a reservoir for human immunodeficiency virus-type 1 (HIV-1) in patients on highly active antiretroviral therapy (HAART) was examined. In a study of 22 patients successfully treated with HAART for up to 30 months, replication-competent virus was routinely recovered from resting CD4+ T lymphocytes. The frequency of resting CD4+ T cells harboring latent HIV-1 was low, 0.2 to 16.4 per 10(6) cells, and, in cross-sectional analysis, did not decrease with increasing time on therapy. The recovered viruses generally did not show mutations associated with resistance to the relevant antiretroviral drugs. This reservoir of nonevolving latent virus in resting CD4+ T cells should be considered in deciding whether to terminate treatment in patients who respond to HAART.

The role of low molecular weight thiols in Mycobacterium tuberculosis.

Low molecular weight (LMW) thiols are molecules with a functional sulfhydryl group that enable them to detoxify reactive oxygen species, reactive nitrogen species and other free radicals. Their roles range from their ability to modulate the immune system to their ability to prevent damage of biological molecules such as DNA and proteins by protecting against oxidative, nitrosative and acidic stress. LMW thiols are synthesized and found in both eukaryotes and prokaryotes. Due to their beneficial role to both eukaryotes and prokaryotes, their specific functions need to be elucidated, most especially in pathogenic prokaryotes such as Mycobacterium tuberculosis (M.tb), in order to provide a rationale for targeting their biosynthesis for drug development. Ergothioneine (ERG), mycothiol (MSH) and gamma-glutamylcysteine (GGC) are LMW thiols that have been shown to interplay to protect M.tb against cellular stress. Though ERG, MSH and GGC seem to have overlapping functions, studies are gradually revealing their unique physiological roles. Understanding their unique physiological role during the course of tuberculosis (TB) infection, would pave the way for the development of drugs that target their biosynthetic pathway. This review identifies the knowledge gap in the unique physiological roles of LMW thiols and proposes their mechanistic roles based on previous studies. In addition, it gives an update on identified inhibitors of their biosynthetic enzymes.

Reverse spikeology: predicting single spikes.

Neural models that simulate single spike trains can help us understand the basic principles of neural coding in vision. Keat et al. (2001) develop a hybrid model that combines spatiotemporal filtering with nonlinear spike generation. The model does a good job of predicting the responses of single retinal ganglion cells and thalamic relay neurons.

A human extrastriate area functionally homologous to macaque V4.

Extrastriate area V4 is crucial for intermediate form vision and visual attention in nonhuman primates. Human neuroimaging suggests that an area in the lingual sulcus/fusiform gyrus may correspond to ventral V4 (V4v). We studied a human neurological patient, AR, with a putative V4v lesion. The lesion does not affect early visual processing (luminance, orientation, and motion perception). However, it does impair hue perception, intermediate form vision, and visual attention in the upper contralateral visual field. Form deficits occur during discrimination of illusory borders, Glass patterns, curvature, and non-Cartesian patterns. Attention deficits occur during discrimination of the relative positions of object parts, detection of low-salience targets, and orientation discrimination in the presence of distractors. This pattern of deficits is consistent with the known properties of area V4 in nonhuman primates, indicating that AR's lesion affects a cortical region functionally homologous to macaque V4.

Comorbidities among HIV-infected injection drug users in Chennai, India.

BACKGROUND & OBJECTIVE: HIV-infected injection drugs users (IDUs) are known to have high rates of co-infections. A few reports exist on comorbidities among HIV-infected IDUs in India. We carried out a retrospective study to analyse data on comorbidities in India and treatment challenges faced when treating HIV-infected IDUs in India. METHODS: A retrospective chart review of 118 HIV-infected IDUs who accessed care at the YRG Centre for Substance Abuse-Related Research, Chennai, between August 2005 and February 2006 was done. Demographic, laboratory and clinical information was extracted from medical records. Descriptive demographic and clinical characteristics and distributions of comorbidities across CD4 cell count strata were analysed. RESULTS: All IDUs were male with a median age of 35.5 yr. The majority were married with average monthly income less than INR 3000 per month. The prevalence of hepatitis B and C infections were 11.9 and 94.1 per cent, respectively. Other common co-morbidities included oral candidiasis (43.2%), tuberculosis (33.9%), anaemia (22.9%), lower respiratory tract infections (16.1%), cellulitis (6.8%), herpes zoster (9.3%) and herpes simplex (9.3%). Among participants with CD4+ < 200 cells/microl, the prevalence of TB was 60 per cent. INTERPRETATION & CONCLUSION: IDUs in Chennai were commonly co-infected with HBV, HCV and tuberculosis, complicating use of antiretroviral and anti-tuberculous therapy. The current regimens available for the management of HIV and TB in India may need to be re-assessed for IDUs given the potential for increased rates of hepatotoxicity.

Object recognition: seeing us seeing shapes.

Our understanding of the neural basis of object recognition is based primarily on work with non-human primates. The problem has recently been addressed in humans using functional magnetic resonance imaging; new results indicate that the lateral occipital complex plays an important role in human object recognition.

CIA, a novel estrogen receptor coactivator with a bifunctional nuclear receptor interacting determinant.

Coregulators for nuclear receptors (NR) are factors that either enhance or repress their transcriptional activity. Both coactivators and corepressors have been shown to use similar but functionally distinct NR interacting determinants containing the core motifs LxxLL and PhixxPhiPhi, respectively. These interactions occur through a hydrophobic cleft located on the surface of the ligand-binding domain (LBD) of the NR and are regulated by ligand-dependent activation function 2 (AF-2). In an effort to identify novel coregulators that function independently of AF-2, we used the LBD of the orphan receptor RVR (which lacks AF-2) as bait in a yeast two-hybrid screen. This strategy led to the cloning of a nuclear protein referred to as CIA (coactivator independent of AF-2 function) that possesses both repressor and activator functions. Strikingly, we observed that CIA not only interacts with RVR and Rev-ErbAalpha in a ligand-independent manner but can also form complexes with estrogen receptor alpha (ERalpha) and ERbeta in vitro and enhances ERalpha transcriptional activity in the presence of estradiol (E(2)). CIA-ERalpha interactions were found to be independent of AF-2 and enhanced by the antiestrogens EM-652 and ICI 182,780 but not by 4-hydroxytamoxifen and raloxifene. We further demonstrate that CIA-ERalpha interactions require the presence within CIA of a novel bifunctional NR recognition determinant containing overlapping LxxLL and PhixxPhiPhi motifs. The identification and functional characterization of CIA suggest that hormone binding can create a functional coactivator interaction interface in the absence of AF-2.

Characterization of a partial alpha-amylase clone from red porgy (Pagrus pagrus): expression during larval development.

A partial alpha-amylase cDNA was isolated from red porgy (Pagrus pagrus, Teleostei: Sparidae) and its tissue specific expression during larval development was examined. The cDNA was 949 bp long and showed 90% identity with other fish amylases. A 545 bp fragment was used to study amylase expression using in situ hybridization and RT-PCR techniques. Both methods showed a similar pattern: high and relatively constant expression for the first 30 days after hatching (dah), subsequently decreasing until the end of the experiment at 60 dah. The goal of this work was to extend the existing knowledge of the functionality of larval fish digestive systems and to provide new information about alpha-amylase gene expression.

The Zn-finger domain of MdmX suppresses cancer progression by promoting genome stability in p53-mutant cells.

The MDMX (MDM4) oncogene is amplified or overexpressed in a significant percentage of human tumors. MDMX is thought to function as an oncoprotein by binding p53 tumor suppressor protein to inhibit p53-mediated transcription, and by complexing with MDM2 oncoprotein to promote MDM2-mediated degradation of p53. However, down-regulation or loss of functional MDMX has also been observed in a variety of human tumors that are mutated for p53, often correlating with more aggressive cancers and a worse patient prognosis. We have previously reported that endogenous levels of MdmX can suppress proliferation and promote pseudo-bipolar mitosis in primary and tumor cells derived from p53-deficient mice, and that MdmX-p53 double deficient mice succumb to spontaneously formed tumors more rapidly than p53-deficient mice. These results suggest that the MdmX oncoprotein may act as a tumor-suppressor in cancers with compromised p53 function. By using orthotopic transplantation and lung colonization assays in mice we now establish a p53-independent anti-oncogenic role for MdmX in tumor progression. We also demonstrate that the roles of MdmX in genome stability and in proliferation are two distinct functions encoded by the separate MdmX protein domains. The central Zn-finger domain suppresses multipolar mitosis and chromosome loss, whereas the carboxy-terminal RING domain suppresses proliferation of p53-deficient cells. Furthermore, we determine that it is the maintenance of genome stability that underlies MdmX role in suppression of tumorigenesis in hyperploid p53 mutant tumors. Our results offer a rationale for the increased metastatic potential of p53 mutant human cancers with aberrant MdmX function and provide a caveat for the application of anti-MdmX treatment of tumors with compromised p53 activity.

Leftward ribosome frameshifting at a hungry codon.

Previous experiments have shown that limitation for certain aminoacyl-tRNA species results in phenotypic suppression of a subset of frameshift mutant alleles, including members in both the (+) and (-) incorrect reading frames. Here, we demonstrate that such phenotypic suppression can occur through a ribosome reading frame shift at a hungry AAG codon calling for lysyl-tRNA in short supply. Direct amino acid sequence analysis of the product and DNA sequence manipulation of the gene demonstrate that the ribosome frameshift occurs through a movement of one base to the left, so as to decode the triplet overlapping the hungry codon from the left or 5' side, followed by continued normal translation in the new, shifted reading frame.

On the mechanism of leftward frameshifting at several hungry codons.

We have used lacZ reporter genes to assess leftward ribosome frameshifting on sequences containing the quadruplet U UUC followed by several different triplets coding for lysine, isoleucine, or leucine. Limitation for lysine-tRNA provokes leftward frameshifting when the slippery quadruplet is followed by either lysine codon aag or aaa, but not when followed by an isoleucine or leucine codon. Limitation for isoleucine provokes frameshifting when the quadruplet is followed by either isoleucine codon aua or auc, but not when it is followed by a lysine codon. We conclude that the quadruplet promotes shifting when the ribosome is stalled at any "hungry" codon immediately after it. Changing the quadruplet to U AGC, at which peptidyl-tRNA cognate to the AGC triplet will be mismatched at all three anticodon positions if it slips left, abolishes frameshifting when the ribosome is stalled at the next position. We conclude that the U UUC quadruplet promotes frameshifting by virtue of its ability to pair with a left-slipped peptidyl-tRNA. The frameshift promoted by isoleucine-tRNA limitation of the U UUC aua sequence was analyzed by amino acid sequencing of the protein product. It occurs through reading of the Cau histidine codon overlapping the hungry codon from the left. This result rules out a "simultaneous slippage" type of mechanism. It strongly suggests instead that starvation-promoted frameshifting occurs primarily by slippage of peptidyl-tRNA just upstream of the stall site, followed by decoding of the triplet overlapping the stall site from the left or 5' side. A secondary finding is that the last base of the "hungry" codon has a moderate effect on its shiftiness, aag being shiftier than aaa, and aua being shiftier than auc.

On the role of the P-site in leftward ribosome frameshifting at a hungry codon.

Previous work characterized ribosomal frameshifting within the sequence C UUC AAG provoked by lysyl-tRNA limitation. The ribosome frameshift is one base to the left of the AAG lysine codon, as shown by dotted overlining above. We now show that the frequency of this leftward ribosome frameshift is strongly influenced by the identity of the bases two, three and four positions to the left of the actual frameshift site. The nature of these influences coincides exactly with the possibilities of base-pairing between the sequence and the anticodon of the P-site peptidyl-tRNA when shifted one base to the left just upstream of the frameshift site. We conclude that a peptidyl shift in the P-site is intimately involved in leftward frameshifting in the adjacent A site when it codes for an aminoacyl-tRNA in short supply.

On the mechanism of ribosomal frameshifting at hungry codons.

In a few, rather rare cases, frameshift mutant alleles are phenotypically suppressed during limitation for particular aminoacyl-tRNA species. The simplest interpretation is compensatory ribosome frameshifting at a "hungry" codon in the vicinity of the suppressed frameshift mutation. We have now tested this interpretation directly by obtaining amino acid sequence data on such a phenotypically suppressed protein. We used a plasmid-borne lacZ gene, engineered to be in the (+) reading frame. Its background leakiness is increased by two orders of magnitude during lysyl-tRNA limitation. The enzyme made under this condition has the amino acid sequence expected from the DNA sequence up to the first lysine codon, then shifts in the (-) direction to recreate the correct lacZ reading frame. The lysine is replaced by serine, presumably due to cognate reading of an overlapping AGC codon displaced by one base to the 3' side of the AAG codon. When the 3' overlapping codon is AGA or AGG, there is no ribosome frameshifting; when it is AGU (read by the same serine tRNA) there is frameshifting, although less efficiently than in the case of AGC. The mechanism of cognate overlapping reading contradicts more elaborate models that two of the authors have suggested previously. However, the possibility remains that there is more than one mechanism of ribosome frameshifting at hungry codons.

Enhanced ribosome frameshifting in stationary phase cells.

We have examined the effect of growth phase in Escherichia coli on the translation of a plasmid-borne lacZ gene in which active enzyme synthesis requires a leftward frameshift. During the log phase of growth, the differential rate of enzyme synthesis is very low. It increases by about two orders of magnitude during the small amount of protein synthesis which occurs at the end of log phase and the early part of stationary phase. The increase is sufficient to increase the enzyme's specific activity in crude extracts to 30 times more than it would be if the log-phase differential rate continued unchanged. No such large increase is observed with a zero-frame lacZ+ control gene on the same plasmid under the control of the same promoter; a significant but much smaller increase is observed with a zero-frame control containing an in-frame terminator triplet in the region of the required frameshift. Protein sequence analysis of the enzyme made from the frameshift reporter in stationary cells shows that the increased enzyme synthesis is due to frameshifting, and not due to termination and reinitiation. The frameshift occurs at or right after the sequence U UUC AAG, an intrinsically shifty site.

On the role of the starved codon and the takeoff site in ribosome bypassing in Escherichia coli.

Translating ribosomes can skip over stretches of messenger RNA and resume protein chain elongation after a "bypassed" region. We have previously shown that limitation for isoleucyl-tRNA can initiate a ribosome bypass when an AUA codon is in the ribosomal A-site. We have now generalized this effect to other "hungry" codons calling for four different limiting aminoacyl-tRNA species, suggesting that a pause at any A-site will have this effect. We have assessed bypassing in a large family of reporters with nearly every different triplet in the "takeoff site", i.e. the P-site on the 5' side of the hungry codon, and an identical "landing site" codon 16 nucleotides downstream. The different takeoff sites vary over a factor of 50 in bypassing proficiency. At least part of this variation appears to reflect stability of the codon Colon, two colons anticodon interaction at the takeoff site, as indicated by the following: (a) the bypassing proficiency of different tRNAs shows a rough correlation with the frequency of A Colon, two colons U as opposed to G Colon, two colons C pairs in the codon Colon, two colons anticodon association; (b) specific tRNAs bypass more frequently from codons ending in U than from their synonym ending in C; (c) an arginine tRNA with Inosine in the wobble position which reads CGU, CGC, and CGA bypasses much more frequently from the last codon than the first two synonyms.