ABSTRACT
Autophagy and inflammation are the important physiological reactions, especially in innate immunity. Autophagy, as a conservative metabolic process, can degrade its own disorder components through lysosomes to maintain cell homeostasis. Autophagy plays a pivotal role in degrading damaged organelles, resisting pathogenic infection and regulating inflammatory response. In the past decades, the study of autophagy in yeast and mammals has greatly increased our understanding for autophagy and its relationship with the diseases. In human, the regulation on autophagy levels can be used to prevent or treat neurodegenerative diseases, inflammatory diseases, tumors and various pathogenic microbial infections. However, in fish, the researches on autophagy and application are limited. Inflammation is a highly complex biological process, which is a natural defense response under the stimulation of ultraviolet, pathogen infection, oxidative stress and mechanical damage. Fish, as a lower vertebrate, has an incomplete acquired immune system. Innate immunity plays an important role in defensing against pathogen infection. Compared with higher vertebrate animals, although the researches on autophagy in fish cells were carried out lately, the great progress has been made in recent years on autophagy phenomenon, expression regulation of autophagy-related genes, and mechanism caused by pathogenic infection. As an important part of innate immunity, autophagy is involved in a variety of fish pathogenic infections, and fish diseases are usually accompanied by inflammatory reaction. In this review, we summarized the update findings in recent references on the autophagy and inflammatory response caused by pathogenic infection in fish, and the correlation between them, in order to deeply understand the correlation relationship between autophagy and inflammatory response in fish. This review could provide the guidance for understanding the immune mechanism of fish, and supply the foundation for developing new strategy to prevent and control fish disease.
ABSTRACT
Cerebral ischemia/reperfusion injury (CIRI) is a common feature and the main pathophysiological mechanism of ischemic stroke(IS), which is caused by a blood reperfusion injury in ischemic brain tissues. It can aggravate brain tissue injury and cause irreversible brain damage, seriously affecting the quality of life or even the life of patients. Hence, we must find out the exact mechanism as well as the effective therapeutic drugs and targets for CIRI. The Chinese medicine effective in Xingnao (restoring consciousness) and Kaiqiao (opening orifices) has been widely used in the treatment of CIRI and serves as a classic therapy for IS. In recent years, scholars have conducted extensive and in-depth studies on the mechanism and therapeutic targets of Chinese medicine in Xingnao and Kaiqiao. They found that those drugs could interfere with a series of changes after IS and achieve the remarkable curative effect. This study summarized the effect and mechanism of Chinese medicine in Xingnao and Kaiqiao in the treatment of CIRI, including reducing the inflammatory response and oxidative stress, alleviating brain edema and the toxicity of excitatory amino acids, reducing cell apoptosis, promoting angiogenesis and neurovascular remodeling, and improving blood-brain barrier injury. It is expected to provide references to clarify the mechanism and important targets of those drugs in resisting CIRI and ideas for the in-depth investigation and application of brain protection of Chinese medicine in Xingnao and Kaiqiao.
ABSTRACT
The fruiting body pattern is an important agronomic trait of the edible fungus Auricularia auricula-judae, and an important breeding target. There are two types of fruiting body pattern: the cluster type and the chrysanthemum type. We identified the fruiting body pattern of 26 test strains, and then constructed two different near-isogenic pools. Then, we developed sequence characterized amplified region (SCAR) molecular markers associated with the fruiting body pattern based on sequence-related amplified polymorphism (SRAP) markers. Ten different bands (189–522 bp) were amplified using 153 pairs of SRAP primers. The SCAR marker “SCL-18” consisted of a single 522-bp band amplified from the cluster-type strains, but not the chrysanthemum strains. This SCAR marker was closely associated with the cluster-type fruiting body trait of A. auricula-judae. These results lay the foundation for further research to locate and clone genes controlling the fruiting body pattern of A. auricula-judae.