Gene/Protein
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Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Drug
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Target Concepts:
Gene/Protein
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Query: UMLS:C0847097 (
acidity
)
15,165
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Acid-base homeostasis depends on glutamine flow from producer organs to those capable of generating bicarbonate. Glutamine oxidation, the prerequisite metabolic transformation, can be expressed by many sites; however, net base generation requires that glutamine flow be directed to a specific organ, the kidney. Normally, glutamine flows from the periphery to the splanchnic bed, providing a major fuel and supporting ureagenesis. Glutamine flow in chronic metabolic acidosis, on the other hand, is rerouted to the kidneys; asymmetrical distribution of NH+4 and HCO3- into the urine and renal vein subserves restoration of alkaline reserves. Clearly, glutamine flows in accordance with physiological demands, yet little is known of the regulatory mechanisms. As a model, chronic metabolic acidosis alters two aspects of this vital flow, its direction and magnitude. Characteristically the direction of flow is away from the splanchnic bed and into the kidneys associated with a marked fall in arterial glutamine concentration, restoring arterial level returns flow to the splanchnic bed sink. Thus glutamine homeostasis is sacrificed to impart direction to interorgan glutamine flow. Although multiple sites contribute to glutamine homeostasis, of great strategic importance is the potent hepatic glutaminase flux activated by portal venous NH+4 fed forward by gut metabolism; local hydrogen ion concentration modulates the effectiveness of this activator. Acute regulation of flow direction can be exerted by the lungs in determining the prevailing pCO2 and cellular
acidity
; respiratory compensation in chronic acidosis allows the expression of hepatic glutaminase, thereby suppressing arterial glutamine concentration. The enormous magnitude of glutamine flowing from muscle to the kidneys is supported by adaptive increases in
glutamine synthetase
and mitochondrial glutaminase, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Interorgan glutamine flow in metabolic acidosis. 332 41
Humic substances (HS) are powerful natural plant biostimulants. However, there is still a lack of knowledge about the relationship between their structure and bioactivity in plants. We extracted HS (THE1-2) from two forest soils covered with
Pinus mugo
(1) or
Pinus sylvestris
(2). The extracts were subjected to weak acid treatment to produce size-fractionated HS (high molecular size, HMS1-2; low molecular size, LMS1-2). HS were characterized for total
acidity
, functional groups, element and auxin (IAA) contents, and hormone-like activity. HS concentrations ranging from 0 to 5 mg C L
-1
were applied to garlic (
Allium sativum
L.) plantlets in hydroponics to ascertain differences between unfractionated and size-fractionated HS in the capacity to promote mineral nutrition, root growth and cell differentiation, activity of enzymes related to plant development (invertase, peroxidase, and esterase), and N (nitrate reductase,
glutamine synthetase
) and S (O-acetylserine sulphydrylase) assimilation into amino acids. A positive linear dose-response relationship was determined for all HS in the range 0-1 mg C L
-1
, while higher HS doses were less effective or ineffective in promoting physiological-biochemical attributes of garlic. Bioactivity was higher for size-fractionated HS according to the trend LMS1-2>HMS1-2>THE1-2, with LMS2 and HMS2 being overall more bioactive than LMS1 and HMS1, respectively. LMS1-2 contained more N, oxygenated functional groups and IAA compared to THE1-2 and HMS1-2. Also, they exhibited higher hormone-like activities. Such chemical properties likely accounted for the greater biostimulant action of LMS1-2. Beside plant growth, nutrition and N metabolism, HS stimulated S assimilation by promoting the enrichment of garlic plantlets with the S amino acid alliin, which has recognized beneficial properties in human health. Concluding, this study endorses that i) treating THE with a weak acid produced sized-fractionated HS with higher bioactivity and differing in properties, perhaps because of novel molecular arrangements of HS components that better interacted with garlic roots; ii) LMS from forest soils covered with
P. mugo
or
P. sylvestris
were the most bioactive; iii) the cover vegetation affected HS bioactivity iv); HS stimulated N and S metabolism with relevant benefits to crop nutritional quality.
...
PMID:Bioactivity of Size-Fractionated and Unfractionated Humic Substances From Two Forest Soils and Comparative Effects on N and S Metabolism, Nutrition, and Root Anatomy of
Allium sativum
L. 3292 15
