Carbohydrate analysis of Mortierella alpina by colorimetry and HPLC-ELSD to reveal accumulation differences of sugar and lipid.

OBJECTIVES: To establish reliable methods for the extraction and quantification of the total carbohydrate and intracellular saccharides from Mortierella alpina and study the changes between carbohydrate and lipid in fermentation process. RESULTS: The extraction of mycelia with HCl following a photometric phenol-sulphuric acid reaction was identified as an optimal method for total carbohydrate analysis in Mortierella alpina, which the extraction efficiency performed 1.1-3.6 fold than other five methods. The total carbohydrate content increased from initial 19.26 to 25.86% during early fermentation process and declined gradually thereafter, while the fatty acid was increasing from 8.47 to 31.03%. For separation and qualitative estimation of intracellular saccharides, the acetonitrile/water freeze-thaw method for extraction and Sugar-Pak I column for separation proved to be possible. With the glucose rapidly decreasing at the beginning of growth, the trehalose accumulated rapidly from 1.63 to 5.04% and then decreased slightly but maintain above 4% of dry biomass. CONCLUSIONS: This work established comprehensive carbohydrate extraction and analysis methods of Mortierella alpina and identified the main saccharide in fermentation process which indicated that the accumulation of fatty acids was related to the change of intracellular carbohydrate content.

Redistributing Carbon Flux by Impairing Saccharide Synthesis to Enhance Lipid Yield in Oleaginous Fungus Mortierella alpina.

Increasing carbon flux toward target metabolites is important in improving microbial productivity and economic value. To improve the efficiency of lipid production in Mortierella alpina, we knocked down genes for trehalose-6-phosphate synthetase (Matps) and phosphoenolpyruvate carboxykinase (Mapepck) in the major pathways for saccharide synthesis. The knockdown of Matps reduced trehalose content by an average of 31.87%, while the knockdown of Mapepck reduced the total saccharide content by 28.6%, and both recombinant strains showed more than 20% increased lipid yield. Trehalose plays a vital role in stress resistance, but a higher polyunsaturated fatty acid-rich lipid content was found to partly compensate for the loss of trehalose after Matps knockdown. As compared with Matps knockdown, the knockdown of Mapepck gave better lipid production by bringing forward the time to maximum lipid yield by three days in a scale-up test. The arachidonic acid yield after the Mapepck knockdown reached 1.23 g/L, which was 39.9% higher than that of the original strain. The present research provided an efficient strategy for redistributing carbon flux among different metabolites and therefore promoted microbial lipid yield in a shorter fermentation period.

Hyaluronan accumulates in demyelinated lesions and inhibits oligodendrocyte progenitor maturation.

Demyelination is the hallmark of numerous neurodegenerative conditions, including multiple sclerosis. Oligodendrocyte progenitors (OPCs), which normally mature into myelin-forming oligodendrocytes, are typically present around demyelinated lesions but do not remyelinate affected axons. Here, we find that the glycosaminoglycan hyaluronan accumulates in demyelinated lesions from individuals with multiple sclerosis and in mice with experimental autoimmune encephalomyelitis. A high molecular weight (HMW) form of hyaluronan synthesized by astrocytes accumulates in chronic demyelinated lesions. This form of hyaluronan inhibits remyelination after lysolecithin-induced white matter demyelination. OPCs accrue and do not mature into myelin-forming cells in demyelinating lesions where HMW hyaluronan is present. Furthermore, the addition of HMW hyaluronan to OPC cultures reversibly inhibits progenitor-cell maturation, whereas degrading hyaluronan in astrocyte-OPC cocultures promotes oligodendrocyte maturation. HMW hyaluronan may therefore contribute substantially to remyelination failure by preventing the maturation of OPCs that are recruited to demyelinating lesions.

Mechanism of acute pancreatitis complicated with injury of intestinal mucosa barrier.

Acute pancreatitis (AP) is a common acute abdomen in clinic with a rapid onset and dangerous pathogenetic condition. AP can cause an injury of intestinal mucosa barrier, leading to translocation of bacteria or endotoxin through multiple routes, bacterial translocation (BT), gut-origin endotoxaemia, and secondary infection of pancreatic tissue, and then cause systemic inflammatory response syndrome (SIRS) or multiple organ dysfunction syndrome (MODS), which are important factors influencing AP's severity and mortality. Meanwhile, the injury of intestinal mucosa barrier plays a key role in AP's process. Therefore, it is clinically important to study the relationship between the injury of intestinal mucosa barrier and AP. In addition, many factors such as microcirculation disturbance, ischemic reperfusion injury, excessive release of inflammatory mediators and apoptosis may also play important roles in the damage of intestinal mucosa barrier. In this review, we summarize studies on mechanisms of AP.

Large-scale generation of highly enriched neural stem-cell-derived oligodendroglial cultures: maturation-dependent differences in insulin-like growth factor-mediated signal transduction.

Multipotent neural stem cells (NSCs) are competent for commitment to the oligodendrocyte (OL) lineage both in vitro and in vivo. We exploited this property to develop a rat neurospheres (NS)/oligospheres (OS)-based culture system to generate large numbers of highly enriched late OL progenitors (preOLs) and mature OLs (MatOLs). CNS neuroblastoma cell line B104-derived conditioned medium promoted the generation of nearly pure populations of preOLs from dissociated OS. The subsequent culture of preOLs with ciliary neurotrophic factor (CNTF) and 3,3',5'-triiodo-L-thyronine (T(3)) generated nearly pure populations of MatOLs. OL lineage specificity was confirmed by immunocytochemistry, quantitative RT-PCR and gene expression profiling, which demonstrated large differences between preOLs and MatOLs. The insulin-like growth factors (IGFs) are potent neuro-protective agents required for OL survival. We used this system to systematically define maturation-dependent changes in IGF signaling during the course of OL differentiation. The IGF-I and insulin receptors, insulin receptor substrate-1 (IRS-1) and IRS-2, protein kinase B (PKB)/Akt and Janus kinase (JNK) were expressed at higher levels in NS and preOLs compared with OS and MatOLs. Erk expression increased markedly from NS to OS, decreased only partially upon commitment to preOLs, and, in MatOLs, returned to a low level similar to NS. IGF activation of the generally proliferative Erk pathway was gradually acquired during NSC differentiation, whereas IGF activation of the generally pro-survival, anti-apoptotic PI3K/PKB pathway was consistently robust at each developmental stage.