Localisation of the Vacuolar Proton Pump (V-H+-ATPase) and Carbonic Anhydrase II in the Human Eccrine Sweat Gland

The localisation of the vacuolar proton pump (V-H+ -ATPase) and the enzyme carbonic anhydrase II (CAII) was investigated in the human eccrine sweat gland employing standard immunohistochemical techniques after antigen retrieval using microwave heat treatment and high pressure. The high-pressure antigen retrieval unmasked the presence of V-H+ -ATPase in the clear cells of the secretory coil, with a distribution similar to that previously observed for CAII. However, the dark cells were unreactive to both antibodies. In addition, heat and high-pressure antigen retrieval demonstrated the presence of CAII in the apical zone of luminal cells of the reabsorptive duct, a location not previously reported. The localisation of V-H+ -ATPase and CAII in the secretory coil clear cells suggests that the formation of HCO3- and H+ by carbonic anhydrase II and the transport of H+ by V-H+ -ATPase may play an role in sweat fluid secretion. Their presence at the apex of the duct cells indicates involvement in ductal ion reabsorption.     

Treatment of diabetic wounds with fetal murine mesenchymal stromal cells enhances wound closure

The dental follicle is a mesenchymal tissue that surrounds the developing tooth germ. During tooth root formation, periodontal components, viz., cementum, periodontal ligament (PDL), and alveolar bone, are created by dental follicle progenitors. Here, we report the presence of PDL progenitors in mouse dental follicle (MDF) cells. MDF cells were obtained from mouse incisor tooth germs and immortalized by the expression of a mutant human papilloma virus type 16 E6 gene lacking the PDZ-domain-binding motif. MDF cells expressing the mutant E6 gene (MDF ^E6-EGFP cells) had an extended life span, beyond 150 population doublings (PD). In contrast, normal MDF cells failed to proliferate beyond 10 PD. MDF ^E6-EGFP cells expressed tendon/ligament phenotype-related genes such as Scleraxis (Scx), growth and differentiation factor-5, EphA4, Six-1, and type I collagen. In addition, the expression of periostin was observed. To elucidate the differentiation capacity of MDF ^E6-EGFP cells in vivo, the cells were transplanted into severe combined immunodeficiency mice. At 4 weeks, MDF ^E6-EGFP cell transplants had the capacity to generate a PDL-like tissue that expressed periostin, Scx, and type XII collagen and the fibrillar assembly of type I collagen. Our findings suggest that MDF ^E6-EGFP cells can act as PDL progenitors, and that these cells may be a useful research tool for studying PDL formation and for developing regeneration therapies. This work was supported by a Grant-in Aid for the High-Tech Research Center Project from the Ministry of Education, Culture, Sports, Science, and Technology of Japan, the AGU High-Tech Research Center Project, the 2003-Multidisciplinary Research Project from MEXT, and grants from the Ministry of Education, Culture, Sports, Science, and Technology of Japan.     

Megapixel digital PCR

We present a microfluidic 'megapixel' digital PCR device that uses surface tension-based sample partitioning and dehydration control to enable high-fidelity single DNA molecule amplification in 1,000,000 reactors of picoliter volume with densities up to 440,000 reactors cm(-2). This device achieves a dynamic range of 10(7), single-nucleotide-variant detection below one copy per 100,000 wild-type sequences and the discrimination of a 1% difference in chromosome copy number.     

Complementary roles of microtubules and microfilaments in the lung fibroblast-mediated contraction of collagen gels: Dynamics and the influence of cell density

Summary Fibroblasts are important cellular components in wound healing, scar formation, and fibrotic disorders; and the fibroblast-populated collagen-gel (FPCG) model allows examination of fibroblast behavior in an in vitro three-dimensional environment similar to that in vivo. Contraction of free-floating FPCGs depends, on an active and dynamic cytoskeleton, and the contraction dynamics are highly influenced by cell density. We investigated mechanistic differences between high- and low-cell density FPCG contraction by evaluating contraction dynamics in detail, using specific cytoskeletal disruptors. Collagen gels were seeded with human lung fibroblasts at either high (HD) or low (LD) density, and incubated with or without cytoskeletal disruptors colchicine (microtubules) or cytochalasin D (microfilaments). Gel area was measured daily. FPCG contraction curves were essentially sigmoidal, featuring an initial period of no contraction (lag phase), followed by a period of rapid contraction (log phase). Contraction curves of HD-FPCGs were distinct from those of LD-FPCGs. For example, HD-FPCGs had a negligible lag phase (compared with 3 d for LD-FPCGs) and exhibited a higher rate of log-phase contraction. Both colchicine and cytochalasin dose-dependently inhibited contraction but specifically affected different phases of contraction in HD- and LD-FPCGs; and colchicine inhibited LD-FPCGs much more than HD-FPCGs. The data indicate that LD- and HD-FPCGs contract through different primary mechanisms. Microtubules and microfilaments are both complementarily and dynamically involved in the contraction of FPCGs, and cell density influences primary cytoskeletal mechanisms. These results provide valuable information about fibroblast behavior in healing and fibrosis, and may suggest novel treatment options.     

Comparative use patterns of plant resources in rural areas of South Africa and Zimbabwe

Documentation of use patterns of plants across national boundaries is of relevance in understanding the importance of plant resources to livelihood strategies of different ethnic groups. Plant resources have gained prominence as a natural asset through which families derive food, firewood, income, medicines and timber, enabling particularly poor communities to achieve self-sufficiency. The objective of this study was to investigate the trends in plant usage in South Africa and Zimbabwe. An ethnobotanical investigation was conducted between January 2012 and January 2013 in the Limpopo Province, South Africa and the Midlands Province, Zimbabwe. The study used questionnaire surveys and interviews with a total of 143 participants to explore plant use patterns in South Africa and Zimbabwe. A total of 98 plant species were identified, with Zimbabwe contributing 70 species and 47 species from South Africa. The uses were classified into 15 categories, major use categories were firewood, food plants, medicine and timber. Food plant was a major plant use category in Zimbabwe, contributing 55.1%, followed by medicinal plants (36.8%), firewood (35.7%) and timber (31.6%). In contrast, firewood was the major plant use category in South Africa, contributing 18.4%, followed by food plants (17.3%), medicinal (14.3%) and timber (1.0%). Comparison of the two countries demonstrated remarkable differences in plant use patterns. The results showed that rural households in Zimbabwe were more reliant on plant resources than their counterparts in South Africa. Such a trend could be attributed to a close relationship between the local people, and their natural and agricultural environment leading to a rich knowledge base on plants, plant use and related practices. This comparative analysis strengthens the firm belief that utilization of plant resources represents an important shared heritage, preserved over the centuries, which must be exploited in order to provide further new and useful body of ethnobotanical knowledge.