Subjects: Biology >> Biochemistry submitted time 2024-04-24
Abstract: How to differentiate the diagnosis of depression and bipolar disorder has always been an important problem that needs to be solved urgently in clinical practice. In this study, from the perspective of urine proteomics, urine samples of similar age were collected from two hospitals to investigate the candidate biomarkers for differentiating the diagnosis of depression and bipolar disorder using both group analysis and one-to-many analysis. The experimental results of the paired group analysis showed that 108 differential proteins were identified in the depressed group compared to the bipolar group under strict screening conditions with screening criteria of FC ≥ 2 or ≤ 0.5 and a two-tailed unpaired t-test of P < 0.01, with an average of 3.7 randomly generated differential proteins, and a confidence level of 96.6 % for the correlation between these proteins and the disease difference. In the one-to-many analysis, 24 differential proteins were co-identified by the samples of 13 depressed patients, 16 of which showed a completely consistent trend of expression changes in all depressed patients studied, and 6 of which were associated with immunoglobulins; 41 differential proteins were co-identified by the samples of 12 depressed patients out of 13, and 19 of which showed a completely consistent trend of expression change in the These results reflect the strong consistency of differential proteins between the two groups of patients. 12 or more samples from depressed patients were enriched for differential proteins related to multiple biological processes and signaling pathways associated with the immune system, which is consistent with previous studies: immune mechanisms may be one of the pathogenetic mechanisms of major depression and that drugs with major immune targets can improve depressive symptoms. In the future, it may be possible to observe the immune status of patients with depression to provide direction and basis for the precise treatment of depression. The results of this paper show that urine proteomics can differentiate between depression and bipolar disorder, suggest possible mechanisms and potential targets for the treatment of depression and bipolar disorder, and provide a tool for future differential diagnosis and precision treatment of the diseases.
Peer Review Status:
Awaiting Review
Subjects: Biology >> Biochemistry Subjects: Biology >> Molecular Biology submitted time 2024-01-25
Abstract: Objective: To explore the possible effects of different sweet taste substances on the body by analyzing the changes of urinary proteome in mice after self-consumption of different sweet taste substances.
Methods: Urine samples of C57BL/6l mice were collected before and after self-consumption of sweet substances, including sucrose, stevia glycosides, acesulfame and sucralose, which are widely used in the world and can cause the preference reaction of mice. Among them, the concentration of non-nutritive sweeteners was selected as the concentration that has been shown to have the strongest preference reaction of mice. Label-free quantitative proteomics using high performance liquid chromatography-tandem mass spectrometry (LC-MS/MS) was used for analysis. Differential proteins of urine proteome were screened in groups for analysis of protein functions and biological pathways. The urine proteome of single mice before and after self-consumption of sweet substances was compared, and the common differential proteins were counted; and the different sweet substances were compared horizontally.
Results and conclusions: Urine proteome can reflect the body changes of mice after self-consumption of sweet substances. And the effects of different sweet substances on urine proteome were different. Among the four sweet substances, sucralose caused the most similar changes in the body compared with sucrose. Compared with sucrose, stevia glycosides caused the most different changes in the body. The body changes caused by sucrose, acesulfame and sucralose are similar, but the body changes caused by stevia glycoside are different from other sweet substances. After self-consumption of the four sweet substances, the urine proteome differential proteins in mice all had proteins that had been reported to be related to brain reward circuitry, while only the urine proteome differential proteins after self-consumption of sucrose, acesulfame and sucralose were mainly related to metabolic processes. Urine proteomic differential proteins after acesulfame of stevia glycoside were mainly related to nucleosome assembly and gene expression.
Peer Review Status:Awaiting Review
Subjects: Biology >> Biochemistry submitted time 2024-01-19
Abstract: Zinc is an essential element for maintaining normal physiological function in living organisms. In this study, 82 mg/kg·d zinc gluconate (equivalent to 11.7 mg/kg·d zinc) was intragastrically administered to rats for 4 days, and the urine proteome of rats before and after short-term intragastric administration of zinc gluconate was compared and analyzed. Many differential proteins have been reported to be zinc related, such as mucin-2 (MUC-2) (14 times before compared with after gavage, p = 0.005) and transthyretin (3.9 times after gavage compared with before gavage, p = 0.0004). Biological processes enriched in differential proteins (e.g., regulation of apoptosis process, immune system process, etc.), molecular functions (e.g., calcium binding, copper binding, signaling receptor activity, etc.), KEGG pathways (e.g., complement and coagulation cascades, PI3K-Akt signaling pathway, etc.) showed correlation with zinc. In this study, we explore the overall effect of zinc on the body from the perspective of urine proteomics, which is helpful to deeply understand the biological function of zinc and broaden the application potential of urine proteomics.
Peer Review Status:Awaiting Review
Subjects: Biology >> Biochemistry submitted time 2024-01-18
Abstract: Calcium is an essential element for maintaining the normal physiological function of organisms. In this study, 3225 mg/kg · d calcium gluconate (equivalent to 300 mg/kg · d calcium) was intragastrically administered to rats for 4 days, and the urine proteome of rats was analyzed. Many differential proteins have been reported to be calcium related, such as Regucalcin (2.6 times higher after gavage than before gavage, p = 0.022), transmembrane protein 132A (8.2 times higher after gavage than before gavage, p = 0.009), creatine kinase (17.5 times higher before gavage than after gavage, p = 0.006), and claudin-3 (13.3 times higher before gavage than after gavage, p = 0.037). Differential protein enriched KEGG pathways included calcium signaling pathways, and biological processes and molecular functions also showed correlation with calcium. In this study, from the perspective of urine proteomics to explore the overall impact of calcium on the body, it is helpful to deeply understand the biological function of calcium and broaden the application potential of urine proteomics.
Peer Review Status:Awaiting Review
Subjects: Biology >> Neurobiology submitted time 2024-01-09
Abstract: Video game addiction manifests as an escalating enthusiasm and uncontrolled use of digital games, yet there are no objective indicators for gaming addiction. This study employed mass spectrometry proteomics to analyze the proteomic differences in the urine of adolescents addicted to gaming compared to those who do not play video games. The study included 10 adolescents addicted to gaming and 9 non-gaming adolescents as a control group. The results showed that there were 125 significantly different proteins between the two groups. Among these, 11 proteins have been reported to change in the body after the intake of psychotropic drugs and are associated with addiction: Calmodulin, ATP synthase subunit alpha, ATP synthase subunit beta, Acid ceramidase, Tomoregulin-2, Calcitonin, Apolipoprotein E, Glyceraldehyde-3-phosphate dehydrogenase, Heat shock protein beta-1, CD63 antigen, Ephrin type-B receptor 4, Tomoregulin-2. Additionally, several proteins were found to interact with pathways related to addiction: Dickkopf-related protein 3, Nicastrin, Leucine-rich repeat neuronal protein 4, Cerebellin-4. Enriched biological pathways discovered include those related to nitric oxide synthase, amphetamine addiction, and numerous calcium ion pathways, all of which are associated with addiction. Moreover, through the analysis of differentially expressed proteins, we speculated about some proteins not yet fully studied, which might play a significant role in the mechanisms of addiction: Protein kinase C and casein kinase substrate in neurons protein, Cysteine-rich motor neuron 1 protein, Bone morphogenetic protein receptor type-2, Immunoglobulin superfamily member 8. In the analysis of urinary proteins in adolescents addicted to online gaming, we identified several proteins that have previously been reported in studies of drug addiction.
Peer Review Status:Awaiting Review
Subjects: Biology >> Biochemistry submitted time 2024-01-04
Abstract: Iron is an essential trace element to maintain the normal physiological function of organisms. No studies have investigated the overall effect of iron on the body from the perspective of urine proteome. In this study, the urine proteome of rats before and after short-term intragastric administration of polysaccharide-iron complex (28mg/kg·d iron, which is equivalent to the dose of anemia prevention in adults) was compared and analyzed by using two analysis methods: individual comparison and group comparison. Many different proteins were reported to be related to iron, including 2', 3' -cyclic nucleotide 3' -phosphodiesterase (CNPase) (7.7 times higher than that after gavage, p=0.0039), p38 (14.5 times higher than that before gavage, p=0.003), etc. In the individual comparison, Hepcidin was up-regulated in 4 rats simultaneously. The biological processes of differential protein enrichment include carbohydrate metabolism, iron ion reaction, apoptosis regulation, hematopoietic progenitor cell differentiation, etc. Molecular functions (e.g., complement binding, hemoglobin binding, etc.), KEGG pathways (e.g., complement and coagulation cascade, cholesterol metabolism, malaria, etc.) have also been shown to be associated with iron. This study contributes to the in-depth understanding of the biological function of iron from the perspective of urine proteomics, and provides a new research perspective for the prevention, diagnosis, treatment and monitoring of iron-related disorders.
Peer Review Status:Awaiting Review
Subjects: Biology >> Biochemistry submitted time 2023-10-11
Abstract: Methods: The urine samples of Recurrent spontaneous abortion (RSA) model mice during implantation (E3.5 and E4.5) and normal pregnant mice during implantation (E3.5 and E4.5) were collected. The protein function and biological pathways were analyzed by non-label quantitative proteomics using high performance liquid chromatography tandem mass spectrometry (LC-MS/MS). Differential proteins (FC > 1.5 or < 0.67, P<0.050) in the urine proteome were screened.
Results: There were 4 mice in RSA model, none of which gave birth. There were 3 normal pregnant mice, and 7, 8 and 9 litters were born respectively at E21. At E3.5, 23 differential proteins could be identified, and at E4.5, 21 differential proteins could be identified. According to Uniprot database and Pubmed database search and related literature reports, nearly half of the differential proteins were associated with implantation. The differential proteins were enriched into a large number of biological pathways related to the implantation process through the David database.
Conclusions: In other words, when the level of human villus gonadotropin in the blood of pregnant women has not changed, and it is impossible to observe and accurately judge pregnancy by existing means, compared with normal pregnant mice, the urine proteome of RSA model mice has changed during the implantation stage, and the known functions of some of the changed proteins are related to implantation.
Peer Review Status:Awaiting Review
Subjects: Biology >> Biochemistry submitted time 2022-09-20
Abstract: The fear of startle is generated in the brain, and urine proteomics was used to explore whether this fear can be detected in the urine. The combination of natural enemy odor and sound stimulation were used to establish a rat model of startle. Urine samples were collected before and after startle and proteomic analysis was performed. The results showed that 22 differential proteins were identified after startle, and the biological pathways enriched in these differential proteins were related to neurotransmitter transport and glucose transmembrane transport, which may be the manifestations of nervous tension caused by startle. Before-after study in single rat was performed and found that there was one differential protein identified samely in five rats, in addition, 19 differential proteins were identified samely in four of five rats, and these proteins were associated with the change of nerve, motion, metabolism and blood pressure, which include catalytic subunits and regulatory subunits of glutamate-cysteine ligase, which realted to the function of startle. These results laid the foundation for the research of startle mechanism, and to find medicine for the treatment of psychological terror target provides a new method. At the same time, it fully illustrates the sensitivity of urine and opens up a new field for the exploration of urine.
Peer Review Status:Awaiting Review
Hits
Hits
Downloads
Comment