In order to investigate the function of watermelon calcium-dependent protein kinase (CDPK) in grafted seedlings and abiotic stress environments, this study used RT-PCR technology to clone the ClCDPK(Cla97C01G019720) gene from watermelon grafted seedlings and performed bioinformatics analysis on it. Further designed specific primers with Kpn Ⅰ and Sal Ⅰ enzyme cleavage sites based on the ClCDPK sequence,conducted amplification and double enzyme cleavage, and connected with pCAMBIA1300 to successfully construct the expression vector pCAMBIA1300-35S-ClCDPK for the target gene.Using RT-qPCR technology, the gene expression levels of ClCDPK were measured in self rooted seedlings (ZG) and grafted seedlings (JJ) after being subjected to salt and drought stress, respectively.The results showed that the ORF of ClCDPK gene was 1 647 bp, encoding 548 amino acids. Its protein contained STKc_CAMK and FRQ1 functional domains, and was a hydrophilic protein. Subcellular localization prediction showed that the protein was located in the nucleus. Evolutionary tree analysis of ClCDPK with CDPK from six other plants revealed that it was closely related to CDPK from Cucurbitaceae melons and pumpkins, with protein sequence homology alignment exceeding 92.64%, indicating high homology.The RT-qPCR expression results showed that the expression level of ClCDPK in grafted seedlings was significantly higher than that in self rooted seedlings. With the duration of stress, the expression levels of ClCDPK in grafted and self rooted seedlings first increased and then decreased, and under the same stress treatment, the expression level of ClCDPK in grafted seedlings was higher than that in self rooted seedlings.This study indicated that ClCDPK responded positively to salt and drought stress, and the ability of grafted seedlings to resist stress was higher than that of self rooted seedlings. It is speculated that ClCDPK is one of the key factors in watermelon's response to grafting, thereby improving the salt and drought resistance of watermelon grafted seedlings.

Serine hydroxymethyltransferase(SHMT),as an important enzyme involved in basic metabolism,plays an important role in plant cell metabolism,photorespiration and defense activities.To understand the bioinformatics function of the SHMT gene family in watermelon,explore its gene expression characteristics under abiotic stress,and provide a basis for the functional development of watermelon SHMT and the breeding of watermelon stress-resistance genes.Bioinformatics methods were used to identify SHMT family,and RT-qPCR was used to analyze the expression patterns of ClSHMTs in different tissues and abiotic stresses.The results showed that 8 ClSHMTs gene family members were identified in the whole genome of watermelon,which were unevenly distributed on 6 chromosomes and named ClSHMT1—ClSHMT8 in turn.There were some differences in the physical and chemical properties of each gene family member,such as the number of amino acids,molecular weight,isoelectric point.The protein contained 471—585 amino acids,with molecular weight of 51.87—65.00 ku and isoelectric point of 6.57—8.52,all of which were hydrophilic proteins.The subcellular localization prediction was mainly distributed on mitochondria.Gene structure and protein conserved motifs analysis showed that the ClSHMTs structure consisted of 4—15 exons and 3—14 introns,and all ClSHMTs contained conserved SHMT domains.Furtherly,phylogenetic analysis with 6 species such as cucumber and wheat showed that 50 SHMTs were divided into 3 sub-families,Group Ⅰ—Ⅲ.Promoter of ClSHMTs contained cis-acting elements related to light response,plant hormone response and stress response.The expression pattern analysis showed that 6 ClSHMTs were expressed in different tissues of watermelon,and the expression levels of ClSHMT1,ClSHMT4,ClSHMT5,ClSHMT8 in leaves were significantly higher than those in other tissues.Under low temperature,drought and salt stress,the expression abundance of ClSHMTs varies,but the expression was mainly up-regulated.In conclusion,this study systematically analyzed the SHMT gene family in watermelon,and will provide a reference for the further study of the biological functions of ClSHMTs.

In order to explore the effects of high temperature stress on different heat-tolerant watermelon inbred lines,heat-sensitive (D27) and heat-tolerant (K53) watermelon seedlings were treated at 42 ℃ for 48 h,and their phenotype,tissue structure,photosynthetic characteristics,antioxidant enzyme activities and osmotic regulators were measured and analyzed every 12 h.The results showed that the leaf thickness,fence tissue thickness,sponge tissue thickness and tissue compactness of heat-tolerant K53 were larger than those of heat-sensitive D27 after high temperature stress.The proportion of sponge tissue in the palisade tissue of D27 decreased more than that of K53.With the increase of high temperature stress time,the net photosynthetic rate (Pn),transpiration rate (Tr) and stomatal conductance (Gs) of the two inbred lines decreased,and the intercellular CO₂ concentration (Ci) increased.And the change amplitude of D27 was greater than that of K53.Among the four photosynthetic pigment contents,the heat-tolerant type was higher than the heat-sensitive type under high temperature stress at different treatment times.The superoxide dismutase (SOD) and peroxidase (POD) of the two inbred lines increased first and then decreased with the increase of high temperature stress time,and the enzyme activity was the highest at 24 h,and the enzyme activity of K53 was significantly higher than that of D27.After high temperature stress,the relative conductivity of the two inbred lines increased,and the relative conductivity of K53 increased less than that of D27.The malondialdehyde (MDA) content of D27 was reduced;the MDA content of K53 decreased after an increase.With the increase of high temperature stress,the soluble protein content and proline content (Pro) of K53 were significantly higher than those of D27 at 24 h.In summary,the heat-tolerant type K53 had a stronger resistance to high temperature stress than the heat-sensitive type D27.

In order to identify the key genes controlling rind hardness and breed crack-resistant watermelon varieties.An F₂ segregating population was created using the high-firmness line 901 and the low-firmness line BSH.Both BSA-seq and RNA-seq approaches were utilized to map the genes responsible for rind hardness.The results of BSA-seq revealed an interval region of 2.14 Mb on chromosome 10,spanning from 1 620 000 to 3 760 000,where the intersection of SNPs and InDels identified 150 candidate genes.Among these,two genes showed non-synonymous mutations,and one gene exhibited a frameshift mutation.Correlation analysis between BSA-seq and RNA-seq identified 6 correlated genes,including Cla97C10G187120, Cla97C10G187020,Cla97C10G187430,Cla97C10G187510,Cla97C10G187280,and Cla97C10G186540.Through bioinformatics analysis,the candidate gene Cla97C10G187120 was identified.The result of qRT-PCR indicated that the transcriptome data was reliable.And the relative expression of the candidate gene Cla97C10G187120 was lower in the line 901 than the line BSH.This study lays a crucial foundation for understanding the molecular mechanisms underlying watermelon rind hardness.

In order to screen out suitable water and nitrogen combinations for watermelons in Yellow River irrigation area of Ningxia, different water and nitrogen treatments were designed to study the effects of water and nitrogen interaction on SPAD value of watermelon leaves, fruit quality,yield and nitrogen uptake and utilization. The results showed that SPAD values were higher by W1N4,W2N3,W2N4,W3N3 and W3N4 treatment,the quality was better under nitrogenous fertilizer amounts at N2 and N3.The yield was the highest under W3N4 treatment,reaching 76 565.36 kg/ha and increased by 8.34% to 37.57% compared with other treatments significantly.Followed by W3N2 and W3N3 treatment.Compared with other levels,when the irrigation water level was W1,the water use efficiency of facility watermelon irrigation was higher.Among them,the irrigation water use efficiency of W1N3 and W1N4 treatment was higher,reaching 43.91,45.32 kg/ha respectively,while it was significantly increased by 14.00% to 56.40% from other treatments.Fruit nitrogen accumulation and total nitrogen accumulation under W3N4 treatment were all the highest compared with other treatments significantly,increasing by 22.75% to 192.36% and 17.00% to 123.39% respectively compared with the other treatments.Partial factor productivity of nitrogen and nitrogen fertilizer utilization rate under W3N2 treatment were all the highest compared with other treatments significantly.Partial factor productivity of nitrogen increased by 11.00% to 343.68%separately compared with the other treatments and nitrogen fertilizer utilization rate increased by 3.34 to 10.02 percentage points compared with other treatments.The correlation analysis showed that SPAD,the center of soluble solids,Vc,yield,irrigation water use efficiency and nitrogen accumulation,were all significantly positively correlated with each other,and they were significantly negatively correlated with partial factor productivity of nitrogen and nitrogen use efficiency,the edge of soluble solids was positively correlated with nitrogen accumulation of the plants,and negatively correlated with partial factor productivity of nitrogen and nitrogen use efficiency.To sum up,the watermelon had better quality when nitrogenous fertilizer amounts were N2(80 kg/ha) and N3(160 kg/ha),the yield-increasing effect was the best under the combination of water amount for W3(2 200 m³/ha)and nitrogenous fertilizer amount for N4(240 kg/ha).The interaction between high amount of irrigation water and nitrogenous fertilizer application is beneficial to the nitrogen absorption in watermelon,and the interaction between low nitrogen application amount and high nitrogenous fertilizer amount is conducive to utilization of nitrogen fertilizer.

Glutamate decarboxylase(GAD)is a cleavage enzyme that catalyzes the decarboxylation of glutamic acid,plays a key role in GABA synthesis pathway and has an important influence on plants' resistance to abiotic stress.Three watermelon GAD gene family members(Cla97C01G007270,Cla97C01G007290 and Cla97C04G079700)were screened by the association analysis of metabolomics and transcriptomes.On this basis,three watermelon GAD family genes were cloned,named ClGAD1,ClGAD2 and ClGAD3 respectively,and their bioinformatics and expression patterns were analyzed.The results showed that the CDS of ClGAD1,ClGAD2 and ClGAD3 were 1 524,1 497 and 1 497 bp,respectively,and the number of amino acids encoded by them was 507,498 and 498,respectively.All three proteins were hydrophilic proteins and were located in mitochondria.It was highly conserved,and the conserved domain was glutamic acid decarboxylase.Its promoter region contained a large number of CAAT-box and TATA-box,as well as corresponding elements related to adversity stress such as MYB and MYC.The secondary structures of the three GAD proteins were mainly α-helix and random coil.The tertiary structures were all homohexamer structures.Phylogenetic tree showed that members of GAD gene family were closest to GAD of Momordica charantia and Arabidopsis thaliana.qRT-PCR analysis indicated that the highest expression levels of ClGAD1 and ClGAD2 were showed in stems,while that of ClGAD3 was showed in flowers.The expression levels of ClGAD1,ClGAD2 and ClGAD3 were the highest under salt stress for 12,24 and 48 h,respectively.Under cold and drought stress,the expression patterns of the three GAD genes were similar,and all of them were expressed in large quantities in the early stage of stress,and the expression of ClGAD3 under abiotic stress was higher than that of the other two family members.The full-length cDNA of three GAD genes in watermelon was obtained,and their bioinformatics and expression patterns were analyzed,which provided an experimental basis for enriching the abiotic stress resistance gene resources of watermelon.

In order to analyze the molecular mechanism of different watermelon peel firmness,and provided a theoretical basis for discovering key genes related to watermelon peel firmness,the high firmness(901)4-1-1-M and low firmness BSH with similar growth period but significant difference in peel hardness were used as experimental materials.The peel with the maximum difference 30 days after pollination was selected for transcriptome sequencing analysis and the Illumina HiSeq^TM sequencing platform was used to analyze the molecular mechanism of different watermelon peel firmness,Real-time fluorescence quantitative PCR (qRT-PCR) was used to verify the sequencing results.A total of 1 085 differentially expressed genes (DEGs) were screened by transcriptome sequencing,including 555 up-regulated genes and 530 down-regulated genes.Gene Ontology(GO)analysis showed that 1 085 DEGs were significantly enriched in cell components,molecular functions and biological processes,including cell wall,cell periphery,external encapsulation structure,extracellular region,tetrapyrrole skeleton,redox enzyme activity,transferase activity and pectin esterase activity.Kyoto Encyclopedia of Genes and Genomes (KEGG)analysis indicated that 19 DEGs,including Cla97C04G075800,Cla97C02G044950,Cla97C09G165820,Cla97C10G195660,Cla97C01G025380,etc.,were enriched in the most significant enrichment biosynthesis of phenylpropanoid,which eventually lead to the metabolites of Syringyl lignin,5-Hydroxy-guaiacy lifnin,Guaiacy lifnin and P-Hydroxy-phenyl lifnin.The correlation coefficient of DEGs expression levels by qRT-PCR and RNA-seq data was 0.791,which indicated that the transcriptome test data were reliable.This study explained the reason of watermelon peel firmness difference between(901)4-1-1-M and BSH from the transcriptional level.