一株感染铜绿假单胞菌的双链RNA噬菌体PaP6的分离和鉴定

【目的】鉴定一株新分离的铜绿假单胞菌噬菌体PaP6的生物学特性。【方法】利用铜绿假单胞菌临床分离株PA038为宿主,从西南医院污水中分离得到一株裂解性噬菌体PaP6,观察其噬斑特点;氯化铯密度梯度离心纯化噬菌体颗粒后,用透射电子显微镜观察噬菌体形态;提取PaP6基因组,通过DNA酶和RNA酶酶切,做基因组酶切图谱分析;按照感染复数(MOI)分别为10、1、0.1、0.01、0.001和0.000 1加入噬菌体和宿主菌,裂解细菌后,测定噬菌体滴度;以MOI=10的比例加入噬菌体和宿主菌,绘制一步生长曲线;用112株铜绿假单胞菌临床分离株检测PaP6宿主谱。【结果】PaP6的噬斑直径约2 mm-4 mm,圆形透明,边缘清晰;PaP6噬菌体呈多面体立体对称的头部,直径约45 nm;酶切图谱表明PaP6基因组对DNase不敏感,对RNase敏感,未酶切基因组具有3节段双链RNA(dsRNA),长度分别约为9.0、4.5、3.5 kb,共约17 kb;当MOI为0.1时PaP6感染其宿主菌产生的子代噬菌体滴度最高,达到3.4×109 PFU/m L;用一步生长曲线描绘了其生长特性;PaP6可以感染40.1%的临床分离株,是一株比较广谱的噬菌体。【结论】首次报道了一株铜绿假单胞菌的ds RNA分节段噬菌体,分类学上属于囊病毒科,该噬菌体具有较广的宿主谱,在噬菌体治疗领域具有应用前景。     

林麝源铜绿假单胞菌噬菌体vB＿PaeM＿PAMD02的生物学特性与全基因组序列分析

【背景】圈养林麝一半以上的死亡是由铜绿假单胞菌引起的化脓性疾病导致。另外,由于细菌的抗性增加,噬菌体是继抗生素后的另一抗菌选择。【目的】以分离自病死林麝肺脏的铜绿假单胞菌为宿主菌分离一株噬菌体,对其进行生物学特性、全基因组序列分析与体内抑菌试验。【方法】通过双层平板法分离纯化一株裂解性噬菌体,测定其裂解谱、最佳感染复数、一步生长曲线、热稳定性、最适生长pH等生物学特性,通过电镜观察其具体形态,进行全基因组测序与序列分析,并进行小鼠体内抑菌试验。【结果】分离到一株裂解性铜绿假单胞菌噬菌体并命名为vB＿PaeM＿PAMD02,该噬菌体具有透明且边缘清晰无晕环的噬菌斑,其裂解谱较窄,最佳感染复数为0.1,裂解潜伏期为40 min,裂解暴发量较高,热稳定性较高,可耐受弱碱环境。其全基因组大小为66 264 bp,GC含量为55.59%,序列注释结果显示该噬菌体具有92个开放阅读框,不含毒力与耐药基因,属于肌尾噬菌体科。小鼠体内抑菌试验结果显示了PAMD02对其宿主菌良好的抑菌效果。【结论】本研究分离的噬菌体PAMD02有较高的裂解效率,对不利环境有较好的耐受性,不含毒力基因与耐药基因,具有应用...     

PH826噬菌体与抗生素联用有效抑制多重耐药铜绿假单胞菌生物被膜的形成

【目的】铜绿假单胞菌(Pseudomonas aeruginosa)是一种重要的革兰氏阴性病原体,可以加重囊性纤维化患者的肺部感染,最终会导致患者的死亡。然而由于多重耐药(multi-drug resistant,MDR)和泛耐药(pan-drug resistant, PDR)铜绿假单胞菌菌株的出现,使其防控变得更为严峻。【方法】从养殖场污水中分离能有效裂解多重耐药铜绿假单胞菌的噬菌体,研究其形态特征、生物学特性、宿主谱范围、基因组特征和体外抑菌能力等,并采用噬菌体和抗生素联用的方法进行生物被膜的抑制试验。【结果】透射电子显微镜的形态分析和基因组分析结合表明,该噬菌体属于Nankokuvirus病毒属。生物学特性试验表明,PH826具有广泛的温度稳定性(4-60℃)和pH稳定性(3.0-11.0)。宿主谱测试显示,PH826可以裂解13株铜绿假单胞菌(包括人源和动物源),体外抑菌试验显示,PH826在感染复数(multiplicity of infection, MOI)分别为10、1、0.1时对铜绿假单胞菌均有强烈的裂解作用。根据基因组分析,PH826噬菌体的基因组大小为87 95...     

PB1样铜绿假单胞菌噬菌体PHW2的生物学特性

【背景】铜绿假单胞菌(Pseudomonas aeruginosa)是一种引起医院感染、急性感染和慢性感染的常见条件致病菌。多重耐药铜绿假单胞菌仍然是引起严重医院感染的常见病菌,其临床治疗面临严峻挑战。噬菌体具有特异性杀菌的能力,在防治铜绿假单胞菌耐药菌方面具有应用前景。【目的】分离能裂解碳青霉烯类耐药的铜绿假单胞菌的噬菌体,分析其生物学特性和基因组特征,为噬菌体治疗储备资源。【方法】采集环境水样,用双层琼脂平板法分离噬菌体,对其形态、一步生长曲线、感染复数等生物学特性进行研究;使用IlluminaMiSeq平台测定噬菌体的全基因组序列,利用Newbler3.0、GeneMarkS、BLASTp、Mauve2.4.0等生物信息软件进行拼接、注释和比较基因组学分析。【结果】分离到一株噬菌体PHW2,该噬菌体属肌尾病毒科成员,可裂解7株碳青霉烯类耐药的铜绿假单胞菌;其最佳感染复数为0.1。一步生长曲线结果显示,其感染宿主菌PA001的潜伏期为100 min,裂解期为360 min,裂解量为25 PFU/cell;噬菌体PHW2在温度25-50℃和pH 6.0-8.0范围内稳定;紫外照射7 min后PHW2活性明显下降;5%氯仿处理100 min内,PHW2仍保持较高的活性。噬菌体PHW2的基因组长65 984 bp,GC含量为55.69%,编码92个ORFs,不含tRNA。基因组比对结果显示PHW2与PB1样噬菌体高度相似。体外生物被膜抑制试验和清除试验结果显示,噬菌体PHW2能显著抑制宿主菌PA001形成的生物被膜并破坏24 h内形成的生物被膜。【结论】分离鉴定了一株新的PB1样噬菌体PHW2,对碳青霉烯类耐药的铜绿假单胞菌裂解能力强。生物学特性、基因组特征、体外生物被膜抑制试验和清除试验结果表明该噬菌体具有治疗铜绿假单胞菌耐药菌的潜力。     

一株假单胞菌属低温噬菌体的分离及其特性研究

目的从纳帕海湿地土样中分离和培养低温菌及其噬菌体,并对其特性进行研究。方法分离纯化低温宿主菌,采用"双层平板法"分离获得噬菌体,通过16S rRNA基因分析对宿主菌进行初步鉴定,对噬菌体进行电镜形态观察,并进行噬菌体基因组酶切片段长度多态性分析及噬菌体生理特性研究。结果从纳帕海土样中分离获得一株裂解性低温噬菌体,命名为SV-12,其宿主菌S-12鉴定为恶臭假单胞菌(Pseudomonas putida)。噬菌体SV-12有囊膜,头部为典型的正六边形,立体对称结构,直径约68.7 nm;尾管长约122.5 nm,直径约25 nm;在4℃时具有侵染活性,4～25℃均能产生边缘清晰、透明的噬菌斑。最适感染温度约为10℃,pH耐受范围较广,在pH=10时具有最多出斑数。结论 SV-12属于肌尾噬菌体科,为裂解性噬菌体,对氯仿极度敏感。基因组为dsDNA,大小约为74 kb。     

一株强裂解性大肠杆菌T1样噬菌体新成员的分离与鉴定

【目的】自然界中噬菌体种类繁多,其裂菌功能在针对细菌耐药方面具有潜在应用价值。不同噬菌体也呈现出显著的基因多样性及宿主特异性。从上海某猪场仔猪肠内容物样品中分离、纯化大肠杆菌的裂解性噬菌体,分析其生物学特性和病毒学特征,为探索应用噬菌体治疗细菌性感染提供研究材料。【方法】采用双层琼脂平板法分离、纯化噬菌体,观察噬菌斑特征,通过电镜观察噬菌体形态特征,测定其裂菌谱、最佳感染复数、一步生长曲线和生物学特性,进行噬菌体全基因组测序和遗传进化分析。【结果】分离、纯化获得一株能高效裂解大肠杆菌K-12菌株的噬菌体,命名为v B_Eco S_SH2(SH2),噬菌斑呈圆形、大而透明、边缘整齐。电镜观察SH2的头部呈二十面体立体对称,尾部较长。噬菌体的潜伏期为10 min,暴发期为60 min,裂解量高达121 PFU/感染细胞,其最佳感染复数为0.1。基因组测序和比对结果表明,SH2的核酸类型为ds DNA,基因组全长为49 088 bp,G+C%含量为45%,Gen Bank登录号为KY985004,结合电镜观察及BLASTp分析,确定其属于有尾噬菌体目长尾噬菌体科成员。同源性及进化分析表明,该噬菌体为大肠杆菌T1样噬菌体的新成员。【结论】分离鉴定了一株裂解效率极高的大肠杆菌T1样噬菌体,并确认其为T1样噬菌体新成员,为研究大肠杆菌噬菌体及其抗菌应用提供了新的实验材料。     

一株粪肠球菌噬菌体的分离及其生物学特性研究

目的:利用临床耐药粪肠球菌分离裂解性噬菌体,为应用噬菌体治疗耐药粪肠球菌感染提供基础。方法:利用噬菌斑实验分离噬菌体并观察噬菌斑形态;双层平板培养法测定噬菌体效价、最佳感染复数及一步生长曲线;负染法电镜观察噬菌体形态;蛋白酶K/SDS法提取噬菌体基因组,酶切处理后琼脂糖凝胶电泳分析。结果:分离出一株噬菌体IME-EF1,该噬菌体能裂解多株临床分离的粪肠球菌;电镜观察呈蝌蚪形,最佳感染复数为1;通过绘制一步生长曲线,证明该噬菌体感染后的潜伏期为25 min,爆发期为35 min,裂解量为60 pfu。结论:研究结果表明利用临床分离的耐药粪肠球菌分离裂解性噬菌体是可行的,有望为耐药粪肠球菌的抗生素替代疗法奠定基础。     

鲍曼不动杆菌噬菌体生物学特性的研究

从污水中分离鉴定鲍曼不动杆菌噬菌体,并对其生物学特性进行分析,为开发针对细菌感染的噬茵体生物制剂提供前期工作.采用双层琼脂法分离可裂解鲍曼不动杆菌的噬菌体,通过负染法电镜观察噬茵体的大小和形态,将噬菌体和宿主菌以不同比例混合,测定噬菌体的最佳感染复数并观察一步生长曲线,提取噬菌体核酸进行酶切电泳分析,通过SDS-PAGE分析噬菌体的结构蛋白和非结构蛋白.成功分离3株可裂解鲍曼不动杆菌的噬菌体(分别命名为ΦAb-1、ΦAb-2和ΦAb-3),电镜显示噬菌体的头部呈二十面体,直径约50nm,有一短尾.噬菌体ΦAb-1的最佳感染复数为10-2,一步生长曲线表明噬菌体在裂解宿主菌时,潜伏期为20 min,爆发期为30 min,裂解量为190 PFU/cell.限制性酶切电泳显示噬菌体ΦAb-1的基因组大小约40 kb左右,为双股环状DNA.SDS-PAGE的噬菌体蛋白电泳包括7种蛋白,分子量在29 ～ 116 ku.噬菌体ΦAb-1、ΦAb-2和ΦAb-3对鲍曼不动杆菌具有很强的裂解毒性.根据其形态、结构和噬菌体分类法,鲍曼不动杆菌噬菌体属于有尾病毒目,足尾病毒科.     

一株粘质沙雷氏菌烈性噬菌体污水分离及特性

[目的]以粘质沙雷氏菌(8039)为宿主菌从医院污水中分离噬菌体并对其基本生物学特点进行研究.[方法]四步法污水分离噬菌体;单、双层平板噬菌斑实验筛选烈性噬菌体并观察噬菌斑形态;纯化后2%磷钨酸染色电镜观察;手工法提取噬菌体核酸酶切后琼脂糖凝胶电泳分析;利用双层平板噬菌斑实验测定最佳感染复数和完成一步生长实验.[结果]从医院污水中成功分离出粘质沙雷氏菌烈性噬菌体一株(SM701),该噬菌体有一个正多面体立体对称的头部,头径约64nm,无囊膜,有一长尾,无收缩尾鞘,尾长约143nm;基因组核酸能被双链DNA内切酶BamH Ⅰ及Hind Ⅲ切开,大小约57kb;噬菌斑圆形透明,直径1mm左右(培养12h,),边界清楚;当感染复数(multiplicity of infection,MOI)为10时,子代噬菌体滴度较高;按照一步生长实验结果绘制出一步生长曲线,可知感染宿主菌的潜伏期是约为30min,爆发期约100min,平均爆发量约为630[结论]按照国际病毒分类委员会分类标准,该噬菌体属于长尾噬菌体科(siphoviridae)烈性噬菌体,按照Bradley和Ackermann形态分类法属于B1亚群;噬菌斑与周围红色细菌生长区,颜色差异明显,非常便于观察和计数;噬菌体头部大小和形态与呼吸道病毒中的呼肠病毒和腺病毒最为接近;国内尚未见粘质沙雷氏菌噬菌体相关报道.     

铜绿假单胞菌噬菌体的分离鉴定及耐噬菌体突变频率测定

用铜绿假单胞菌为宿主菌自污水中分离到3株不同的铜绿假单胞菌噬菌体,命名为PaP1、PaP2及PaP3者均为DNA双链噬菌体,基因组大小分别约为47kb、34kb及24kb。3株噬菌体原液滴度（pfu）分别为109/mL、1011/mL和1011/mL。PaP1为裂菌性噬菌体,PaP2及PaP3为溶原性噬菌体。电镜观察,3株噬菌体头部均为多面体立体对称颗粒,直径分别约为70nm、55nm和65nm。PaP1属肌尾噬菌体科,PaP2和PaP3属短尾噬菌体科。研究中还发现了铜绿假单胞菌的耐噬菌体现象及耐受菌与敏感菌之间的“菌群交替”现象,经测定铜绿假单胞菌耐噬菌体的突变机率在1.4×10-7～7.9×10-7之间。     

驯化噬菌体提高噬菌体对碳青霉烯类耐药肺炎克雷伯菌的杀菌能力

【目的】本研究旨在通过驯化提高噬菌体的裂解能力并降低其宿主菌耐受性产生的速度,从而提高对重要病原菌-碳青霉烯类耐药肺炎克雷伯菌(carbapenem-resistant Klebsiella pneumoniae, CRKp)的杀菌效果。【方法】以临床CRKp菌株Kp2092为宿主菌,利用双层琼脂平板法从污水中分离噬菌体并分析其裂解谱;对其中的广谱强裂解性噬菌体通过透射电镜观察其形态特征并进行全基因组测序;通过噬菌体-宿主连续培养进行噬菌体驯化,并比较驯化前后噬菌体生物学特性的差异。【结果】分离得到的9株肺炎克雷伯菌噬菌体中,噬菌体P55anc裂解能力强且裂解谱广,透射电镜观察发现其为短尾噬菌体。P55anc基因组全长40 301 bp,包含51个编码序列,其中27个具有已知功能,主要涉及核酸代谢、噬菌体结构蛋白、DNA包装和细胞裂解等。噬菌体P55anc经9 d的驯化后,得到3株驯化噬菌体。驯化后噬菌体杀菌能力增强,主要表现为细菌生长曲线显著下降、噬菌体暴发量增多、裂解谱扩大,且宿主菌对其产生抗性的概率显著降低。与此同时,驯化后的噬菌体在热处理、紫外暴露以及血清等环境下保持较好的稳定性。【结论】利用噬菌体-宿主连续培养的方法可对噬菌体进行驯化和筛选,驯化后的噬菌体杀菌效果更强,且在不同压力处理下的稳定性良好,而细菌产生噬菌体抗性的概率也降低。     

The complete nucleotide sequence of phi CTX, a cytotoxin-converting phage of Pseudomonas aeruginosa: implications for phage evolution and horizontal gene transfer via bacteriophages

phi CTX is a cytotoxin-converting phage isolated from Pseudomonas aeruginosa. In this study, we determined the complete nucleotide sequence of the phi CTX phage genome. The precise genome size was 35,538 bp with 21 base 5'-extruding cohesive ends. Forty-seven open reading frames (ORFs) were identified on the phi CTX genome, including two previously identified genes, ctx and int. Among them, 15 gene products were identified in the phage particle by protein microsequencing. The most striking feature of the phi CTX genome was an extensive homology with the coliphage P2 and P2-related phages; more than half of the ORFs (25 ORFs) had marked homology to P2 genes with 28.9-65.8% identity. The gene arrangement on the genome was also highly conserved for the two phages, although the G + C content and codon usage of most phi CTX genes were similar to those of the host P. aeruginosa chromosome. In addition, phi CTX was found to share several common features with P2, including the morphology, non-inducibility, use of lipopolysaccharide core oligosaccharide as receptor and Ca(2+)-dependent receptor binding. These findings indicate that phi CTX is a P2-like phage well adapted to P. aeruginosa, and provide clear evidence of the intergeneric spread and evolution of bacteriophages. Furthermore, comparative analysis of genome structures of phi CTX, P2 and other P2 relatives revealed the presence of several hot-spots where foreign DNAs, including the cytotoxin gene, were inserted. They appear to be deeply concerned in the acquisition of various genes that are horizontally transferred by bacteriophage infection.     

Classification of 17 newly isolated virulent bacteriophages of Pseudomonas aeruginosa

Seventeen virulent bacteriophages specific to Pseudomonas aeruginosa strains were isolated by screening various environmental samples. These isolated bacteriophages were grouped based on results obtained from restriction fragment analysis of phage genomes, random amplification of polymorphic DNA (RAPD) typing, morphology observations under transmission electron microscope, and host range analysis. All 17 bacteriophages are double-stranded DNA viruses and can be divided into 5 groups based on DNA restriction profiles. A set of 10-mer primers was used in RAPD typing of phages, and similar conclusions were obtained as for restriction fragment analysis. One phage was randomly selected from each of the 5 groups for morphology observations. Four of them had an icosahedral head with a long contractile tail, belonging to the Myoviridae family, and one phage had an icosahedral head with a short tail, thereby belonging to the Podoviridae family. Host range experiments were conducted on 7 laboratory strains and 12 clinical strains of P.?aeruginosa. The results showed that 13 phages had the same infection profile, killing 8 out of 19 tested P.?aeruginosa strains, and the remaining 4 phages had different and unique infection profiles. This study highlights the diversity of bacteriophages specific to P.?aeruginosa in the environment.     

欧文氏菌噬菌体的分离纯化及生物学特性研究

以欧文氏菌胡萝卜亚种为宿主菌,从环境污泥中分离到10株噬菌体.噬菌体热稳定性、pH稳定性分析结果表明噬菌体Erj2、Erb1、Erc2在温度-20～40℃、pH4.0～9.0之间均表现出良好的稳定性.噬菌体生物学特性分析显示,它们的最佳感染复数分别为0.0001、0.001、0.0001;核酸类型均为双链DNA;一步生...     

Biological consequences of infection of Escherichia coli B by alkylated T7 bacteriophage.

Alkylation of T7 bacteriophage considerably delayed phage development and reduced the phage's killing action on host cells. Only a small fraction of infected cells produced phage. For these phages, the latent period was markedly prolonged but the burst was equivalent to or only slightly lower than that of untreated phage. In the progeny of alkylated phage, there was an increase in the fraction of defective particles as well as a change in their morphology. These data show that infection with alkylated T7 bacteriophage is to a large degree abortive; hence, biological consequences of this infection are very different from those characteristic of a normal virus infection.     

两株副溶血弧菌烈性噬菌体的分离鉴定

研究旨在筛选烈性噬菌体, 为副溶血弧菌(Vibrio parahaemolyticus, Vp)病害防控增加新的选择。以副溶血弧菌Vp13为宿主菌, 通过二层琼脂平板法筛选, 分离到了2株烈性噬菌体SX-2和SX-F。对其形态结构进行了透射电镜观察, 利用DNase I、 RNase A、Mung Bean Nuclease和Hind Ш酶进行噬菌体核酸类型鉴定, 并对噬菌体的裂解谱、最佳感染复数、一步生长曲线进行了测定。透射电镜观察结果显示: SX-2核衣壳头部长约110 nm, 宽约50 nm, 尾部长约150 nm, 宽约10 nm, 为典型的复合体制; SX-F核衣壳呈正六边形, 长约为56.86 nm,宽约50.74 nm, 未观察到尾部, 推测为正二十面体对称; 核酸测定结果显示两者均为线性双链DNA。依据国际病毒分类委员会第九次报告, SX-2符合肌尾噬菌体科特征, SX-F符合盖噬菌体科特征。噬菌体SX-2和SX-F对85株弧菌裂解结果显示: 噬菌体SX-2能够裂解23株副溶血弧菌和1株溶藻弧菌(Vibrio alginolyticus), 噬菌体SX-F能够裂解19株副溶血弧菌和1株溶藻弧菌。SX-2和SX-F的最佳感染复数均为0.0001。一步生长曲线结果显示: SX-F的潜伏期约10min, 裂解期约70min, 裂解量为116.2; 噬菌体SX-2的潜伏期小于10min, 裂解期大约70min, 裂解量为209.3。两株噬菌体生物学特性表明SX-2与SX-F均为烈性噬菌体, 这为进一步探讨噬菌体防治技术奠定了基础。     

Characterization of Newly Isolated Lytic Bacteriophages Active against Acinetobacter baumannii

Based on genotyping and host range, two newly isolated lytic bacteriophages, myovirus vB_AbaM_Acibel004 and podovirus vB_AbaP_Acibel007, active against Acinetobacter baumannii clinical strains, were selected from a new phage library for further characterization. The complete genomes of the two phages were analyzed. Both phages are characterized by broad host range and essential features of potential therapeutic phages, such as short latent period (27 and 21 min, respectively), high burst size (125 and 145, respectively), stability of activity in liquid culture and low frequency of occurrence of phage-resistant mutant bacterial cells. Genomic analysis showed that while Acibel004 represents a novel bacteriophage with resemblance to some unclassified Pseudomonas aeruginosa phages, Acibel007 belongs to the well-characterized genus of the Phikmvlikevirus. The newly isolated phages can serve as potential candidates for phage cocktails to control A. baumannii infections.     

Basic characterization of a Pseudomonas aeruginosa PAO1 bacteriophage

A bacteriophage of Pseudomonas aeruginosa PAO1 was characterized. Bacteriophage PIK was found to adsorb on the cell wall of the host organism. Electron microscopy of the phage PIK revealed that it had a bipyramidal hexagonal prismatic head of 110 nm in diameter, a tail which was 158 nm long and a tail plate of 47 nm width. This paper describes its basic characters, and a quantitative study was made of its adsorption to exponential phase cells of two different strains of P. aeruginosa. PIK was found to contain double stranded DNA and it appears to be virulent towards its host, P. aeruginosa PAO1. It was classified into the group of phages possessing a contractile tail.     

Polysaccharide depolymerase associated with bacteriophage infection

Bartell, Pasquale F. (University of Pennsylvania, Philadelphia), Thomas E. Orr, and Grace K. H. Lam. Polysaccharide depolymerase associated with bacteriophage infection. J. Bacteriol. 92:56-62. 1966.-A recently isolated bacteriophage of Pseudomonas aeruginosa was observed, in association with bacteria, to produce a polysaccharide depolymerase. Exposure of slime polysaccharide to the enzyme at the pH optimum of 7.5 for 30 to 60 min resulted in a decreased viscosity of 20 to 25%, and a measurable increase in the levels of hexosamines, hexoses, and reducing substances, distinguishing it from other phage-associated depolymerases. Like egg-white lysozyme, the depolymerase produced a clearing of mature bacterial lawns, but was shown to be devoid of muralytic activity by turbidimetric and paper chromatographic analysis. The depolymerase reacted with polysaccharides of only certain strains of P. aeruginosa, and there appeared to be no correlation with phage susceptibility. The enzyme was not detectable in uninfected cultures, nor was it synthesized when infection was initiated by phages other than phage 2. The available data suggest that the genetic information required for biosynthesis of this enzyme is furnished by the phage 2 genome.     

Characterization of lytic Pseudomonas aeruginosa bacteriophages via biological properties and genomic sequences

Pseudomonas aeruginosa is an important cause of infections, especially in patients with immunodeficiency or diabetes. Antibiotics are effective in preventing morbidity and mortality from Pseudomonas infection, but because of spreading multidrug-resistant bacterial strains, bacteriophages are being explored as an alternative therapy. Two newly purified broad host range Pseudomonas phages, named vB_Pae-Kakheti25 and vB_Pae-TbilisiM32, were characterized as candidates for use in phage therapy. Morphology, host range, growth properties, thermal stability, serology, genomic sequence, and virion composition are reported. When phages are used as bactericides, they are used in mixtures to overcome the development of resistance in the targeted bacterial population. These two phages are representative of diverse siphoviral and podoviral phage families, respectively, and hence have unrelated mechanisms of infection and no cross-antigenicity. Composing bactericidal phage mixtures with members of different phage families may decrease the incidence of developing resistance through a common mechanism.