基于ROC曲线的非亲缘造血干细胞捐献志愿者筛选标准

目的：基于ROC曲线分析方法探讨非亲缘造血干细胞捐献志愿者筛选标准。方法：采用问卷调查法收集温州市2007年至2018年间共40名成功捐献造血干细胞志愿者以及166名尚未完成捐献的入库志愿者信息,构建捐献认知、捐献意愿、捐献态度及三种得分联合检验的ROC曲线。结果：综合了捐献认知、捐献意愿及捐献态度的联合筛选方法ROC曲线下面积为0.87（95%CI：0.81～0.93）,灵敏度为70.00%,特异度为90.96%,一致率为86.89%,Youden指数为0.61。结论：增强入库志愿者对非亲缘造血干细胞捐献的认知程度,提高入库志愿者的捐献意愿与态度,有利于提高志愿者的捐献可能性,降低悔捐率。     

Regulation of photosystem I light harvesting by zeaxanthin

In oxygenic photosynthetic eukaryotes, the hydroxylated carotenoid zeaxanthin is produced from preexisting violaxanthin upon exposure to excess light conditions. Zeaxanthin binding to components of the photosystem II (PSII) antenna system has been investigated thoroughly and shown to help in the dissipation of excess chlorophyll-excited states and scavenging of oxygen radicals. However, the functional consequences of the accumulation of the light-harvesting complex I (LHCI) proteins in the photosystem I (PSI) antenna have remained unclarified so far. In this work we investigated the effect of zeaxanthin binding on photoprotection of PSI–LHCI by comparing preparations isolated from wild-type Arabidopsis thaliana (i.e., with violaxanthin) and those isolated from the A. thaliana nonphotochemical quenching 2 mutant, in which violaxanthin is replaced by zeaxanthin. Time-resolved fluorescence measurements showed that zeaxanthin binding leads to a previously unrecognized quenching effect on PSI–LHCI fluorescence. The efficiency of energy transfer from the LHCI moiety of the complex to the PSI reaction center was down-regulated, and an enhanced PSI resistance to photoinhibition was observed both in vitro and in vivo. Thus, zeaxanthin was shown to be effective in inducing dissipative states in PSI, similar to its well-known effect on PSII. We propose that, upon acclimation to high light, PSI–LHCI changes its light-harvesting efficiency by a zeaxanthin-dependent quenching of the absorbed excitation energy, whereas in PSII the stoichiometry of LHC antenna proteins per reaction center is reduced directly.In eukaryotic photosynthetic organisms, photosystem I (PSI) and photosystem II (PSII) comprise a core complex hosting cofactors involved in electron transport and an outer antenna system made of light-harvesting complexes (LHCs): Lhcas for PSI and Lhcbs for PSII. The core complexes bind chlorophyll a (Chl a) and β-carotene, whereas the outer antenna system, in addition to Chl a, binds chlorophyll b (Chl b) and xanthophylls. Despite their overall similarity, PSI and PSII differ in the rate at which they trap excitation energy at the reaction center (RC), with PSI being faster than PSII (1–9). They also differ in their structure (10–12). PSI is monomeric and carries its antenna moiety on only one side as a half-moon–shaped structure whose size is not modulated by growth conditions (13, 14). PSII, on the other hand, is found mainly as a dimeric core surrounded by an inner layer of antenna proteins (Lhcb4–6) and an outer layer of heterotrimeric LHCII complexes (Lhcb 1–3) whose stoichiometry varies depending on the growth conditions (7, 12, 13, 15). Acclimation to high irradiance leads to a lower number of trimers per PSII RC accompanied by loss of the monomeric Lhcb6. These slow acclimative responses regulate the excitation pressure on the PSII RC, preventing saturation of the electron transport chain (16) and the oxidative stress in high light (HL), leading to photoinhibition. The response to rapid changes in light level is managed by turning on some photoprotective mechanisms, such as the nonphotochemical quenching (NPQ) of the excess energy absorbed by PSII (16), which is activated by the acidification of the thylakoid lumen and protonation of the trigger protein PsbS or LhcSR. Low luminal pH also activates violaxanthin de-epoxidase (VDE), catalyzing the de-epoxidation of the xanthophyll violaxanthin to zeaxanthin (17, 18), a scavenger of reactive oxygen species (ROS) produced by excess light (9, 13). Zeaxanthin also enhances NPQ, as observed in vivo by a decrease of PSII fluorescence (19). The short-term effects of exposure to HL on PSI have been disregarded thus far. Because of its rapid photochemistry, PSI shows low fluorescence emission, implying a low ¹Chl* concentration and a low probability that chlorophyll triplet states will be formed by intersystem crossing. This characteristic suggests that the formation of oxygen singlet excited states (¹O*₂) is reduced and that NPQ phenomena in photoprotection are less relevant in PSI (20, 21). Nevertheless, several reports have shown that, especially in the cold (22–29), PSI can exhibit photo-inhibition, with its Lhca proteins being the primary target (24, 30). Upon synthesis in HL, zeaxanthin binding could be traced to two different types of binding site. One, designated “V1,” is located in the periphery of LHCII trimers (31–33). The second, designated “L2,” has an inner location in the dimeric Lhca1–4 and the monomeric Lhcb4–6 members of the LHC family (34–37). Experimental determination of the efficiency of the violaxanthin-to-zeaxanthin exchange yielded a maximal score in the Lhca3 and Lhca4 subunits (24, 25). Interestingly, Lhca1/4 and Lhca2/3 are bound to the PSI core as dimers that can be isolated in fractions identified as “LHCI-730” and “LHCI-680,” respectively, both accumulating zeaxanthin to a de-epoxidation index of ∼0.2 (20, 38). Lhca3 and Lhca4 carry low-absorption-energy chlorophyll forms known as “red forms” (39, 40) that are responsible for the red-shifted PSI emission peak at 730–740 nm at 77 K. The molecular basis for red forms is an excitonic interaction of two chromophores: chlorophylls 603 and 609 located a few angstroms from the xanthophyll in site L2, which can be either violaxanthin or zeaxanthin depending on light conditions (41, 42). It is unclear whether the binding of zeaxanthin to the PSI–LHCI complex has specific physiological function(s) or is simply a result of its common origin with Lhcb proteins.The goal of this study was to understand whether zeaxanthin plays a role in PSI–LHCI photoprotection. To investigate the role of zeaxanthin bound to Lhca proteins, we analyzed the changes in antenna size and Chl a fluorescence dynamics in PSI supercomplexes binding either violaxanthin or zeaxanthin. We found a zeaxanthin-dependent regulation of PSI antenna size and an enhanced resistance to excess light upon zeaxanthin binding. These results show that dynamic changes in the efficiency of light use and in photoprotection capacity are not exclusive to PSII, as previously thought; instead, eukaryotic photosynthetic organisms modulate the function of both photosystems in a coordinated manner.     

PGC-1β promotes enterocyte lifespan and tumorigenesis in the intestine

The mucosa of the small intestine is renewed completely every 3–5 d throughout the entire lifetime by small populations of adult stem cells that are believed to reside in the bottom of the crypts and to migrate and differentiate into all the different populations of intestinal cells. When the cells reach the apex of the villi and are fully differentiated, they undergo cell death and are shed into the lumen. Reactive oxygen species (ROS) production is proportional to the electron transfer activity of the mitochondrial respiration chain. ROS homeostasis is maintained to control cell death and is finely tuned by an inducible antioxidant program. Here we show that peroxisome proliferator-activated receptor-γ coactivator-1β (PGC-1β) is highly expressed in the intestinal epithelium and possesses dual activity, stimulating mitochondrial biogenesis and oxygen consumption while inducing antioxidant enzymes. To study the role of PGC-1β gain and loss of function in the gut, we generated both intestinal-specific PGC-1β transgenic and PGC-1β knockout mice. Mice overexpressing PGC-1β present a peculiar intestinal morphology with very long villi resulting from increased enterocyte lifespan and also demonstrate greater tumor susceptibility, with increased tumor number and size when exposed to carcinogens. PGC-1β knockout mice are protected from carcinogenesis. We show that PGC-1β triggers mitochondrial respiration while protecting enterocytes from ROS-driven macromolecule damage and consequent apoptosis in both normal and dysplastic mucosa. Therefore, PGC-1β in the gut acts as an adaptive self-point regulator, capable of providing a balance between enhanced mitochondrial activity and protection from increased ROS production.The intestine represents the interface between the organism and its luminal environment and is constantly challenged by mechanical stress, diet-derived toxins and oxidants, and endogenously generated reactive oxygen species (ROS), which can induce serious damage to all biological molecules and cell structures (1). To preserve cellular integrity and tissue homeostasis, the intestine possesses self-renewing capacity via the continuous migration of new enterocytes that undergo differentiation from the crypt to the apical compartment of the villus, where they become competent to apoptosis and are shed into the lumen. ROS accumulation within intestinal epithelial cells promotes apoptotic cell death in the differentiated compartment (2). The mitochondrial electron transport chain is a major site of ROS production in the cells. Under physiological conditions, the balance between ROS generation and detoxification is controlled by a set of cellular enzymes including superoxide dismutase and catalase. Important components of the ROS-scavenging pathways are linked to mitochondrial oxidative metabolism via the peroxisome proliferator-activated receptor-γ coactivators 1α and 1β (PGC-1α and PGC-1β), apparently enabling cells to maintain normal redox status in response to changing oxidative capacity (3). PGC-1α and PGC-1β are master regulators of mitochondrial biogenesis and oxidative metabolism as well as antioxidant defense. Both PGC-1α and PGC-1β are preferentially expressed in tissues with high oxidative capacity where they participate, through mitochondrial biogenesis, in the metabolic response to high energy demand (4), such as cold-adapted thermogenesis in brown adipose tissue (5), fiber-type switching in striated muscle (6), and fatty acid β oxidation and gluconeogenesis in liver during a fasting state (7, 8). The increase in mitochondrial biogenesis and activity stimulated by PGC-1 proteins may cause an increase in the production of ROS. However, PGC-1α also has been shown to increase the expression of the major mitochondrial antioxidant enzyme superoxide dismutase 2 (Sod2) (3, 9). Therefore, PGC-1α is able to upgrade aerobic energy metabolism while preserving ROS homeostasis, by simultaneously promoting ROS formation and detoxification. Recently, it has been shown in Drosophila that the PGC-1α homolog spargel is able to induce mitochondrial function and oxygen consumption, which is coupled to the induction of scavenger systems and ROS reduction, finally leading to increased longevity (10). On the other hand, in the differentiated intestinal epithelium of mice, PGC-1α induces mitochondrial biogenesis and oxygen consumption, but it is not able to induce the ROS-scavenging apparatus, thus promoting ROS-dependent apoptotic cell death (2).PGC-1β is highly similar to PGC-1α, both in amino acid sequence and ability to regulate several metabolic pathways (8, 11). Therefore, in the present study we focus on the function of PGC-1β in the intestinal epithelium, giving special attention to the effect of this coactivator in enterocyte homeostasis. We first show that PGC-1β is highly expressed in intestinal epithelium with an almost ubiquitous pattern of localization along the entire crypt–villus axis. To study its activation, we generated mice overexpressing PGC-1β selectively in the enterocytes. We show that in these cells PGC-1β enhances mitochondrial biogenesis and respiration and induces a parallel increase in antioxidant enzymes, such as Sod2 and glutathione peroxidase 4 (Gpx4), as well as peroxiredoxins. As a result, the intestinal morphology is severely affected, with significant increases in enterocyte longevity and mucosal villi length. Concomitantly, PGC-1β overexpression leads to a significant increase in tumor number and size in two distinct models of intestinal carcinogenesis. Moreover, to confirm the role of PGC-1β activity in the intestine, we also generated intestinal-specific PGC-1β (iPGC-1β) knockout mice that, in line with the evidence from transgenic mice, show reduced expression of several metabolic pathways and mitochondrial antioxidant systems as well as decreased susceptibility to tumors. Indeed, tumors may use adaptive mechanisms to keep their ROS burden within a range that permits their growth and survival. In such contest, PGC-1β acts as a gatekeeper of redox status, allowing enterocyte survival and, in cancer-promoting conditions, tumor progression.     

Rickettsial Infections in Southeast Asia: Implications for Local Populace and Febrile Returned Travelers

Rickettsial infections represent a major cause of non-malarial febrile illnesses among the residents of Southeast Asia and returned travelers from that region. There are several challenges in recognition, diagnosis, and management of rickettsioses endemic to Southeast Asia. This review focuses on the prevalent rickettsial infections, namely, murine typhus (Rickettsia typhi), scrub typhus (Orientia tsutsugamushi), and members of spotted fever group rickettsiae. Information on epidemiology and regional variance in the prevalence of rickettsial infections is analyzed. Clinical characteristics of main groups of rickettsioses, unusual presentations, and common pitfalls in diagnosis are further discussed. In particular, relevant epidemiologic and clinical aspects on emerging spotted fever group rickettsiae in the region, such as Rickettsia honei, R. felis, R. japonica, and R. helvetica, are presented. Furthermore, challenges in laboratory diagnosis and management aspects of rickettsial infections unique to Southeast Asia are discussed, and data on emerging resistance to antimicrobial drugs and treatment/prevention options are also reviewed.     

How Many Have Died from Undiagnosed Human Immunodeficiency Virus–Associated Histoplasmosis,A Treatable Disease? Time to Act

Human immunodeficiency virus (HIV)–associated disseminated Histoplasma capsulatum capsulatum infection often mimics tuberculosis. This disease is well know in the United States but is dramatically underdiagnosed in Central and South America. In the Amazon region, given the available incidence data and the regional HIV prevalence, it is expected that, every year, 1,500 cases of histoplasmosis affect HIV patients in that region alone. Given the mortality in undiagnosed patients, at least 600 patients would be expected to die from an undiagnosed but treatable disease. The lack of a simple diagnostic tool and the lack of awareness by clinicians spiral in a vicious cycle and made a major problem invisible for 30 years. The HIV/acquired immunodeficiency syndrome community should tackle this problem now to prevent numerous avoidable deaths from HIV-associated histoplasmosis in the region and elsewhere.In the Guianas and the Amazon Basin, the prevalence of human immunodeficiency virus (HIV) is approximately 1%. There have been some decreases in incidence in some states in this region, but recent increases in incidence in northern states of Brazil have been reported.^1–3 The population of the Amazon basin is estimated to be approximately 10 million persons,⁴ which would imply that approximately 100,000 persons are HIV positive in the Amazon Basin.The Amazonian environment is suitable for the growth of Histoplasma capsulatum.⁵ For immunocompetent patients, this organism causes mostly benign infections, but in severely immunodepressed HIV-infected patients, infection with this organism leads to a fatal disease in the absence of diagnosis and treatment. There lies the problem. Clinical symptoms are unspecific and often mimic those of tuberculosis.^6,7 Diagnosis is difficult and requires invasive procedures (biopsies, bone marrow smears), and trained staff to detect H. capsulatum, often after weeks of culture.⁸ Severe infections are often fatal within days.⁹ However, death often occurs after long delays in which patients are unsuccessfully treated for unconfirmed tuberculosis. Patients die because they are not treated for a treatable disease and because there is no diagnosis test. With no diagnosis, this possibility is not included in the diagnostic and treatment algorithms of clinicians who, despite unknowingly encountering this disease on a regular basis, have never seen a case because it was never diagnosed. In this context, then why give presumptive treatment of a disease that is not present?It is tragic but it makes total sense. It is even frighteningly tragic when one crunches the numbers to estimate what it means that after 30 years of the HIV epidemic, one of the leading causes of acquired immunodeficiency syndrome (AIDS) in the Amazon¹⁰ still goes largely unrecognized and evolves under the radar of national plans and international funding efforts.The only incidence data available for this region suggests that the incidence of histoplasmosis during the highly active antiretroviral therapy era was 1.5 cases/100 person-years.¹⁰ The historical mortality rate of disseminated histoplasmosis was > 30% despite mycology expertise.^7,8 This finding indicates that for 100,000 HIV patients, there would be 1,500 cases of histoplasmosis/year and 600 deaths/year, and probably more if undiagnosed. This finding also indicates that for more than 30 years the cumulated death rate in the region must have been huge, in the tens of thousands.A rational sceptic could rightly doubt this claim from the generalization of data from the smallest South American territory to the entire Amazon and elsewhere. However, when one reviews the literature, it becomes evident that histoplasmosis is present throughout the region, this fact has been known for decades, and that we should have been paying more attention.⁵ The high prevalence of histoplasmin test reactivity in the region was known even before AIDS was identified in 1981.¹¹ Histoplasmosis has been an AIDS-defining illness since 1993. We should have connected the dots earlier.How could something so huge escape the attention of the HIV/AIDS community in the region? One explanation for this dramatic blind spot is that in the region, the diagnostic capacity for mycology has been insufficient. It has been long argued that medical mycology is a neglected area of biology, and that the often low incidence of mycoses is caused by a lack of medical mycologists rather than the absence of the mycoses.¹² Another explanation is that the standard conceptualization of HIV/AIDS, the usual indicators, and the Joint United Nations Programme on HIV/AIDS terminology and framework did not explicitly entail disseminated histoplasmosis or the regional AIDS-defining illnesses. The anesthetic effect of the familiarity of vertical concepts and vertical programs can make it difficult to reframe the problem and see what was always there.For better diagnostic and treatment, we should know what AIDS is to direct diagnostic hypotheses when caring for individual patients. Misdiagnosing histoplasmosis as tuberculosis, not only delays a life-saving treatment of the individual patient, but it can confound tuberculosis statistics (incidence, resistance, mortality) and make it difficult to evaluate tuberculosis program results.The current financial difficulties should not stand in the way of building the diagnostic capacity for detection of histoplasmosis. It does not necessarily cost much to do the diagnosis. Treatment relies on amphotericin B for severe forms and itraconazole for non-severe forms and prophylaxis.⁷ Both drugs are generic drugs that are perfectly affordable. The toxicity of amphotericin B leads industrialized countries to use the costly liposomal version of the drug. However, The Drugs for Neglected Disease Initiative is releasing a cheap alternative that was developed for treatment of cryptococcosis.¹³ This is an opportunity for resource-limited countries in disease-endemic areas for treatment of histoplasmosis. We should not wait any longer. Every year wasted to build capacity for diagnosis and treatment of histoplasmosis in the Amazon Basin and elsewhere leads to hundreds of deaths that could have been avoided. This is not acceptable.     

A novel DPP IV-resistant C-terminally extended glucagon analogue exhibits weight-lowering and diabetes-protective effects in high-fat-fed mice mediated through glucagon and GLP-1 receptor activation

Aims/hypothesis

Modification of the structure of glucagon could provide useful compounds for the potential treatment of obesity-related diabetes.

Methods

This study evaluated N-acetyl-glucagon, (d-Ser²)glucagon and an analogue of (d-Ser²)glucagon with the addition of nine amino acids from the C-terminal of exendin(1-39), namely (d-Ser²)glucagon-exe.

Results

All analogues were resistant to dipeptidyl peptidase IV degradation. N-Acetyl-glucagon lacked acute insulinotropic effects in BRIN BD11 cells, whereas (d-Ser²)glucagon and (d-Ser²)glucagon-exe evoked significant (p?d-Ser²)glucagon-exe stimulated cAMP production (p?GLP-1-receptor (GLP-1R)-transfected cells but not in glucose-dependent insulinotropic polypeptide-receptor-transfected cells. In normal mice, N-acetyl-glucagon and (d-Ser²)glucagon retained glucagon-like effects of increasing (p?d-Ser²)glucagon-exe was devoid of hyperglycaemic actions but substantially (p?d-Ser²)glucagon-exe reduced the glycaemic excursion (p?p?d-Ser²)glucagon-exe. Twice-daily administration of (d-Ser²)glucagon-exe to high-fat-fed mice for 28 days significantly (p?p?p?2 consumption and locomotor activity were (p?p?p?p?p?Conclusions/interpretation This study emphasises the potential of (d-Ser²)glucagon-exe for the treatment of obesity-related diabetes.     

Laparoscopic adjustable gastric banding and progression from impaired fasting glucose to diabetes

Aims/hypothesis

Obesity and dysglycaemia are major risk factors for type 2 diabetes. We determined if obese people undergoing laparoscopic adjustable gastric banding (LAGB) had a reduced risk of progressing from impaired fasting glucose (IFG) to diabetes.

Methods

This was a retrospective cohort study of obese people with IFG who underwent LAGB. Weight and diabetes outcomes after a minimum follow-up period of 4 years (mean ± SD 6.1?±?1.7 years) were compared with those of Australian adults with IFG from a population-based study (AusDiab).

Results

We identified 281 LAGB patients with baseline IFG. Their mean ± SD age and BMI were 46?±?9 years and 46?±?9 kg/m², respectively. The diabetes incidence for patients in the lowest, middle and highest weight loss tertile were 19.1, 3.4 and 1.8 cases/1,000 person-years, respectively. The AusDiab cohort had a lower BMI (28?±?5 kg/m²) and a diabetes incidence of 12.5 cases/1,000 person-years. This increased to 20.5 cases/1,000 person-years when analysis was restricted to the 322 obese AusDiab participants, which was higher than the overall rate of 8.2 cases/1,000 person-years seen in the LAGB group (p?=?0.02). Multivariable analysis of the combined LAGB and AusDiab data suggested that LAGB was associated with ～75% lower risk of diabetes (OR 0.24 [95% CI 0.10, 0.57], p?=?0.004).

Conclusions/interpretation

In obese people with IFG, weight loss after LAGB is associated with a substantially reduced risk of progressing to diabetes over ≥4 years. Bariatric surgery may be an effective diabetes prevention strategy in this population.