Influence of insulin and glucagon on protein metabolism and resting metabolic rate

Pacy, P. J. H.

January 1988

No description available.

612

Diabetes/protein metabolsim

The effect of tricyclic antidepressant drugs on the uptake and metabolism of serotonin by the pineal gland in organ culture

Pillay, Manoranjenni

05 April 2013

The effect of tricyclic antidepressants (TADs) on a variety of pineal functions was assessed. TADs affected the uptake of ³H-5HT into bovine pineal slices within a particular concentration range of these drugs, DESI, CLOMI and IMI appeared to inhibit uptake slightly, within a limited concentration range. Surprisingly, DESI appeared to be a relatively potent 5HT uptake inhibitor. The 5-HT re-uptake system in the pineal probably differes from that in brain tissue. TADs had a marked effect on the metabolism of ³H-5HT in the rat pineal, in an organ culture system, MEL and N-acetylserotonin synthesis increased for the first 11 days and thereafter a slight decrease was observed. HTOH and HIAA also showed an initial increase followed by a slight decrease in synthesis. The synthesis of MTOH and MIAA was decreased. The possibility that TADs could affect HIOMT and SNAT synthesis and thereby change the metabolic pattern of 5-HT was investigated. TADs appeared to stimulate SNAT initially and thereafter a slight decrease from peak activity was observed. This is probably due to stimulation followed by development of subsensitivity of β-receptors, HIOMT activity also appeared to be affected by TADs. The existence of two types of HIOMT is suggested. There is a possibility that these changes in the metabolism of 5-HT could be implicated in the mechanism of action of TADs. / KMBT_363 / Adobe Acrobat 9.53 Paper Capture Plug-in

Antidepressants

Pineal gland -- Metabolsim

Serotonin

Symplasmic pathway in phloem loading and unloading in source and sink leaves of Zea mays L. as evidenced under normal and elevated CO₂ conditions

Nogemane, Noluyolo

January 2003

Zea mays plants kept at ambient (ca 375ppm) and elevated CO₂ (ca 650 to 700ppm) were used to examine the possibility of a symplasmic loading, unloading and transport pathway in dark-adapted and illuminated (200μmolm⁻²sec⁻¹ ) sink and source leaves. 5,6-carboxyfluorescein diacetate was introduced into the mesophyll cells and symplasmic transfer observed 3h after application. In sink and source leaves exposed to ambient CO₂ and illuminated at 200 molm-2sec-1, the fluorescence front was observed approximately 3cm from the point of application, while in dark-adapted plants, the fluorescence front was observed approximately 1cm from the point of application. Under elevated CO₂ conditions the fluorescence front in illuminated plants appeared to transport faster moving approximately 5cm from the point of application, and in dark-adapted plants, only 3cm from the point of application. Based on the increase in 5,6-CF accumulation under elevated CO₂ conditions, the present study suggests that there was an increase in capacity for assimilate loading and transport under elevated CO₂ conditions. In source leaves, 5,6-CFDA was taken up into the mesophyll cells, loaded symplasmically and transported basipetally. In sink leaves 5,6- CFDA was taken up from basal mesophyll and after symplasmic loading, was transported acropetally where it was offloaded into the younger immature sink region. Transport in the sieve tubes was confirmed by using aniline blue, which was applied 3h after 5,6-CF transport. Aniline blue coupled with 5,6-CF transport studies showed that the sieve tubes of both cross and longitudinal veins are involved in symplasmic unloading, loading and transport processes in sink and source leaves. Apoplasmic uptake of 5,6-CFDA by cut leaves showed that after apoplasmic transport via the transpiration stream, 5,6-CFDA was offioaded to the xylem parenchyma where it was metabolically cleaved , releasing fluorescent 5,6-CF into the xylem parenchyma. Transverse sections cut after 3h of uptake were observed after 120 and 180 min suggesting that a retrieval of solutes occurs from the xylem to the xylem parenchyma, bundle sheath, phloem parenchyma and to the th in-walled sieve tubes. It was not possible to determine if the thick-walled sieve tubes were involved or if they took up 5,6-CF. Given the available data on loading and offioading of assimilates in sink and source leaves respectively, this study demonstrated that a slow symplasmic pathway exists from the mesophyll to the phloem, and that offloading from the phloem in sink leaves can occur via a symplasmic route.

Phloem

Plant translocation

Plant cells and tissues

Corn -- Metabolsim

EXTRARIBOSOMAL REGULATION OF MYELOID LEUKEMOGENESIS BY RPL22

Harris, Bryan

January 2019

Mutations and deletions in ribosomal proteins are associated with a group of diseases termed ribosomopathies. Collectively, these diseases are characterized by ineffective hematopoiesis, bone marrow failure, and an increased risk of developing myelodysplastic syndrome (MDS) and subsequently acute myeloid leukemia (AML). This observation highlights the role of dysregulation of this class of proteins in the development and progression of myeloid neoplasms. Analysis of gene expression in CD34+ hematopoietic stem cells (HSC) from 183 MDS patients demonstrated that ribosomal protein L22 (Rpl22) expression exhibited a greater reduction than any other ribosomal protein gene in MDS. Interestingly, we observed that AML patients with lower expression of Rpl22 had a significant reduction in their survival (TCGA cohort, N=200, Log Rank P value<0.05). To assess the mechanism of reduced expression, we developed a FISH probe complementary to the RPL22 locus and assessed for deletion of this locus in an independent set of 104 MDS/AML bone marrow samples. Strikingly, we found that RPL22 deletion was enriched in high-risk MDS and secondary AML cases. We, therefore, sought to investigate whether reduced Rpl22 expression played a causal role in leukemogenesis. Using Rpl22-/- mice, we found that Rpl22-deficiency resulted in a constellation of phenotypes resembling MDS. Indeed, Rpl22-deficiency caused a macrocytic reduction in red blood cells, dysplasia in the bone marrow, and an expansion of the early hematopoietic stem and progenitor compartment (HSPC). Since MDS has been described as a disease originating from the stem cell compartment, we next sought to determine if the hematopoietic defects were cell autonomous and resident in Rpl22-/- HSC. Competitive transplantation revealed that Rpl22-/- HSC exhibited pre-leukemic characteristics including effective engraftment, but a failure to give rise to downstream mature blood cell lineages. Importantly, there was a strong myeloid bias in those downstream progeny derived form Rpl22-/- HSC. To determine how Rpl22-deficiency increased the causes these deficiencies in HSC, we performed whole transcriptome analysis on Rpl22-/- HSC. Interestingly, alterations in genes associated with both ribosomal proteins and mitochondrial components were observed. We found that protein synthesis was unchanged in Rpl22-deficient HSCs, sharply contrasting the reductions in global protein synthesis that usually accompany ribosomal protein insufficiency. Consequently, we shifted our focus to the dysregulated mitochondrial genes, which were linked to the processes of oxidative phosphorylation and fatty acid metabolism. We observed that oxidative phosphorylation was decreased in Rpl22-deficient HSCs while fatty acid oxidation was increased. Increased fatty acid oxidation is associated with maintenance of the hematopoietic stem cells. Interestingly, inhibiting fatty acid oxidation mitigated this attribute in Rpl22 deficient HSCs. Because Rpl22 is an RNA-binding protein, we asked if Rpl22 was regulating fatty acid oxidation by directly binding mRNAs encoding regulators of fatty acid oxidation. We found that Rpl22 is able to directly bind the coding region of an upstream regulator of fatty acid oxidation, Alox12. Thus, we hypothesized that Rpl22-deficiency increased fatty acid oxidation through increased expression of Alox12. Consistent with this hypothesis, knockdown of Alox12 impaired the function of Rpl22 deficient HSC. Because the increased fatty acid oxidation promotes self-renewal of Rpl22-deficient HSC and blocks their differentiation, we also hypothesized that this would predispose them to leukemogenesis. We examined the potential for Rpl22-deficient HSPC to be transformed upon ectopic expression of the MLL-AF9 oncogenic fusion. Indeed, Rpl22 deficiency increased predisposition to transformation both in vitro and in vivo, in MLL-AF9 knockin mice. Furthermore, Rpl22 deficient leukemias were preferentially sensitive to pharmacologic inhibition of fatty acid oxidation or Alox12 knockdown, indicating that leukemia cell survival was also dependent upon fatty acid oxidation. Taken together, these findings indicate that Rpl22-insufficiency predisposes HSPC to leukemic transformation and aggressive growth by regulating mitochondrial function, providing an explanation for the reduced survival observed in Rpl22-low AML patients. We also sought to determine how Rpl22 may be contributing to another subset of AML known as Therapy-related AML. Most commonly, these patients develop AML after previously being treated with an alkylating chemotherapeutic drug. Interestingly, we found that Rpl22-deficient HSPC are resistant to treatment with these agents, despite having evidence of DNA damage. The ultimate consequence of the insensitivity of Rpl22-deficient HSPC to alkylating agents was that mice given serial doses of cyclophosphamide exhibited an increased incidence of leukemic-like changes. This chemo-resistant phenotype in Rpl22-/- cells was related to increased expression of the DNA repair protein MGMT. Inhibition of this protein abrogated the ability of these cells to survive following treatment with cyclophosphamide. Ultimately, this study implicates Rpl22 as a regulator of alkylating DNA damage repair and suggests that both patients with hematologic or solid cancers that express reduced levels of Rpl22 are at increased risk for development of therapy related AML is they are treated with alkylating agents. / Cancer Biology & Genetics

Cellular Biology

Acute Myeloid Leukemia

Extraribosomal

Hematopoietic Stem Cell

Metabolsim

Myelodysplastic Syndrome

Rpl22