When you hear the word "bacteria," you probably picture organisms that couldn't be seen unless they're placed under a microscope. A bacterium that has now been classified as the largest in the world ever discovered, however, needs no special tools to be visible to the naked eye. Thiomargarita magnifica, as it's called, takes on a filament-like appearance and can be as long as a human eyelash. As the BBC notes, that makes it bigger than some more complex organisms, such as tiny flies, mites and worms. It was first discovered by marine biologist Olivier Gros living on sunken mangrove tree leaves in the French Caribbean back in 2009. 

Due to the organism's size, Gros first thought he was looking at a eukaryote rather than simpler prokaryotic organisms like bacteria. It wasn't until he got back to his laboratory that he found out that it wasn't the case at all. Years later, Jean-Marie Volland and his team at the Lawrence Berkeley National Laboratory in California took a closer look at the bacterium using various techniques, such as transmission electron microscopy, to confirm that it is indeed a single-cell organism. They've recently published a paper describing the centimeter-long bacterium in Science.

Volland said T. magnifica is "5,000 times bigger than most bacteria" and is comparable to an average person "encountering another human as tall as Mount Everest." One other information Volland's team has discovered is that the bacterium keeps its DNA organized within a structure that has a membrane. In most bacteria, DNA materials just float freely in their cytoplasm. Further, it has around 6,000 billion bases of DNA. "For comparison, a diploid human genome is approximately six giga (billion) bases in size. So this means that our Thiomargarita stores several orders of magnitude more DNA in itself as compared to a human cell," said team member Tanja Woyke. 

While the scientists know that T. magnifica grows on top of mangrove sediments in the Caribbean and that it creates energy to live using chemosynthesis, which is similar to photosynthesis in plants, there's still a lot about it that remains a mystery. And it'll likely take some time before the scientists can discover its secrets: They have yet to figure out how to grow the organism in the lab, so Gros has to gather samples every time they want to run an experiment. It doesn't help that the organism has an unpredictable life cycle. Gros told The New York Times that he couldn't even find any over the past two months. 

Volland and his team now aim to find a way to grow T. magnifica in the lab. As for Gros, he now expects other teams to go off in search of even bigger bacteria, which like T. magnifica, may also be hiding in plain sight.

When you hear the word "bacteria," you probably picture organisms that couldn't be seen unless they're placed under a microscope. A bacterium that has now been classified as the largest in the world ever discovered, however, needs no special tools to be visible to the naked eye. Thiomargarita magnifica, as it's called, takes on a filament-like appearance and can be as long as a human eyelash. As the BBC notes, that makes it bigger than some more complex organisms, such as tiny flies, mites and worms. It was first discovered by marine biologist Olivier Gros living on sunken mangrove tree leaves in the French Caribbean back in 2009. 

Due to the organism's size, Gros first thought he was looking at a eukaryote rather than simpler prokaryotic organisms like bacteria. It wasn't until he got back to his laboratory that he found out that it wasn't the case at all. Years later, Jean-Marie Volland and his team at the Lawrence Berkeley National Laboratory in California took a closer look at the bacterium using various techniques, such as transmission electron microscopy, to confirm that it is indeed a single-cell organism. They've recently published a paper describing the centimeter-long bacterium in Science.

Volland said T. magnifica is "5,000 times bigger than most bacteria" and is comparable to an average person "encountering another human as tall as Mount Everest." One other information Volland's team has discovered is that the bacterium keeps its DNA organized within a structure that has a membrane. In most bacteria, DNA materials just float freely in their cytoplasm. Further, it has around 6,000 billion bases of DNA. "For comparison, a diploid human genome is approximately six giga (billion) bases in size. So this means that our Thiomargarita stores several orders of magnitude more DNA in itself as compared to a human cell," said team member Tanja Woyke. 

While the scientists know that T. magnifica grows on top of mangrove sediments in the Caribbean and that it creates energy to live using chemosynthesis, which is similar to photosynthesis in plants, there's still a lot about it that remains a mystery. And it'll likely take some time before the scientists can discover its secrets: They have yet to figure out how to grow the organism in the lab, so Gros has to gather samples every time they want to run an experiment. It doesn't help that the organism has an unpredictable life cycle. Gros told The New York Times that he couldn't even find any over the past two months. 

Volland and his team now aim to find a way to grow T. magnifica in the lab. As for Gros, he now expects other teams to go off in search of even bigger bacteria, which like T. magnifica, may also be hiding in plain sight.

A team of almost 100 scientists part of the Telomere-to-Telomere (T2T) Consortium has successfully sequenced the most complete human genome yet. If you're thinking "Wait a minute — didn't scientists produce the complete human genome sequence almost two decades ago?" Well, you wouldn't be wrong. The Human Genome Project finished sequencing 92 percent of the human genome back in 2003, but the techniques available at the time left the remaining 8 percent out of reach until recent years. Thus, 200 million DNA bases remained a mystery for the longest time. 

In a series of papers published in Science, the T2T Consortium has reported how it managed to fill in almost all of the missing spots except for five, leaving only 10 million and the Y chromosome only vaguely understood. After the papers went out, the consortium's scientists have revealed on Twitter that they have figured out the correct assembly for the Y chromosome and that they will publish another paper with the latest results.

Research lead Evan Eichler from the University of Washington likened sequencing a DNA to solving a jigsaw puzzle. Scientists have to break the DNA into small parts and then use sequencing machines to piece them together. Older tools could only sequence small sections of DNA at once, so it's like solving those unnecessarily tough puzzles with tens of thousands of repetitive, almost identical pieces. Newer tools can sequence longer segments of DNA, which makes finding the correct sequence much more achievable.

To make the process less complicated, the team used a cell line from a failed pregnancy called a mole, wherein the sperm enters an egg that doesn't have its own set of chromosomes. That means the team only had to sequence one set of DNA instead of two. Then, they used a technique called Oxford Nanopore to complete assemblies of centromeres, which are dense knobs in the middle of chromosomes. Oxford Nanopore has a relatively high error rate, however, making it less than ideal for sequencing sections with repetitive DNA. For those regions, the team used another technique called PacBio HiFi, which can sequence shorter sections with 99.9 percent accuracy. 

Eichler said the previously unknown genes include ones for immune response that help us survive plagues and viruses, genes that help predict a person's response to drugs and genes responsible for making human brains larger than other primates'. "Having this complete information will allow us to better understand how we form as an individual organism and how we vary not just between other humans but other species," Eichler said. 

The consortium's work cost a few million dollars to achieve, but sequencing is getting cheaper and cheaper with new technologies. Adam Phillippy, another lead author for the studies, said the hope is for individual genome sequencing to cost as little as $1,000 within the next decade. That could make DNA sequencing a part of routine medical tests, which might help doctors create tailor-made treatments for individuals.