Effect of Apium Graveolens (Celery) Seed Extract on Serum Uric Acid Level of Hyperuricemic Rats and its Comparison with Allopurinol

Background: Plant derived medicines are widely used in traditional culture all over the world. Objectives: To determine the effect of Celery Seed Extract (CSE) on uric acid levels in hyperuricemic rats and to compare the effect of allopurinol and CSE. Methods: It was an animal experimental research study. Group A served as negative control whereas Group B served as positive control. CSE was given orally to three groups of rats (C, D, and E). One hour prior to administration of CSE; potassium oxonate was injected intraperitoneally in all groups except negative control to induce hyperuricemia. Similarly, group F was given allopurinol one hour after injection of potassium oxonate. Blood samples were collected for uric acid estimation. Results: It was found that administration of both CSE (group C, D, E) and allopurinol (group F) significantly lowered serum uric acid levels (p<0.001) as compared to positive control (group B). Serum uric acid lowering effect of both drugs CSE and allopurinol was found to be statistically significant on day 3rd and day 7th and was almost comparable. Conclusions: Celery seed extract significantly reduces serum uric acid levels in potassium oxonate-induced hyperuricemic rats and its uric acid lowering effect was comparable with that of allopurinol.

Potential Protective Effect of Dl-3-n-Butylphthalide on Chronic Cerebral Ischemia Brain Injury

: Chronic cerebral ischemia is one of the common ischemic cerebrovascular diseases. Chronic cerebral ischemia can lead to brain dysfunction, and its pathophysiological mechanism involves inflammation, blood-brain barrier destruction, oxidative stress, and other factors. Due to it being difficult to detect, it is easily overlooked, and it is often only observed following onset of cognitive dysfunction. At present, there are few drugs for this treatment. DL-3-N-BUTYLPHTHALIDE (NBP), a compound extracted from celery seed, may play an important role in protecting against brain damage caused by chronic cerebral ischemia. Therefore, we pay more attention to the prevention and treatment of NBP on chronic cerebral ischemia.

First report of ‘Candidatus Liberibacter solanacearum’ on carrot in Serbia

At the beginning of July 2020, three-month-old carrot plants (Daucus carota L. variety Maestro F1) grown in a commercial field 1.2 ha in size at the Begeč locality (45°14’30.38” N 19°36’44.82” E) in southern part of the Bačka region, Vojvodina, Serbia, exhibited symptoms of yellowing and reddish leaf discoloration. At the end of July, leaves on the infected plants became bronze and purplish, while their shoots and roots were stunted due to dehydration, with pronounced proliferation. In some cases, the damage was so extensive that it led to plant decay. The disease incidence of 0.5−1% recorded early in July rapidly escalated, reaching 10−15% in the first ten days of August. The observed symptoms resembled those caused by ‘Candidatus Liberibacter solanacearum’ (CaLso), a phloem-limited proteobacterium (1). To detect and identify CaLso, 15 symptomatic diseased and 5 asymptomatic healthy carrot plants were subjected to conventional polymerase chain reactions (PCR) using two primer sets specific to CaLso, and positive PCR products were further sequenced using commercial facilities (Macrogen Europe). Total DNA was extracted from petiole and root tissues using a commercial kit (Qiagen DNEasy Plant Mini Kit) following the manufacturer-recommended protocol. In the first PCR, using the Lso TX 16/23 F/R primer pair that targets the 16S-23S rRNA IGS region specific to CaLso (2), all 15 diseased samples yielded a band of 383 bp size. After sequencing, 100% homology was noted among tested isolates; therefore, one isolate coded as 1842/20 was chosen as representative and was deposited in NCBI GenBank under Accession number MT948144. BLAST analysis showed 99.70% identity of Serbian carrot isolates with those of the CaLso isolate 80022 originating from celery seed in Slovenia or Italy (Acc. no. KY619977) (3), as well as 99.41% identity with isolate GBBC_Clso_03 from carrot in Belgium (Acc. no. MH734515) and 98.22% identity with the sequence of the CaLso reference strain NZ082226 (Acc. no. EU834130) isolated from tomato in New Zealand (4). In the second PCR, species-specific forward primer LsoF empirically designed at the signature region of the 16S rRNA sequence of CaLso (5) in combination with the universal liberibacter reverse primer OI2c (6) yielded a target of 1163 bp size in all 15 diseased symptomatic carrot samples. Representative isolate 1842/20 was deposited in NCBI GenBank under Acc. no. MW187524. Based on the nucleotide BLAST analysis, the sequence of Serbian carrot isolate showed 100% identity with CaLso strains 16-004 and 16-011 originating from carrot in Finland (Acc. no. MG701014 and MG701015, respectively) and 99.64% identity with CaLso reference strain NZ082226 (Acc. no. EU834130). Five healthy asymptomatic carrot plant samples were negative for the presence of CaLso in both PCR tests employed in this work. To our knowledge, this is the first report of CaLso causing the disease in carrot in Serbia. These results suggest a wider distribution of this pathogen than previously reported in Europe. In 2014, Psyllid Bactericera trigonica (Hemiptera, Triozidae) was described for the first time as a potential vector for CaLso transmission in few localities, including Begeč (7). Considering that its vectors are presently unidentified, certain aspects of CaLso genomics, diversity, epidemiology and vector dynamics will be studied further in future investigations.