CLOSE
Rob Carr, Getty Images
Rob Carr, Getty Images

What Happens to the Losing Team's Pre-Printed Championship Shirts?

Rob Carr, Getty Images
Rob Carr, Getty Images

Following a big win in the Super Bowl, World Series, NBA Finals, or any other major sporting event, fans want to get their hands on championship merchandise as quickly as possible. To meet this demand and cash in on the wallet-loosening "We’re #1" euphoria, manufacturers and retailers produce and stock two sets of T-shirts, hats and other merchandise that declare each team the champ.

Apparel for the winning team quickly fills clothing racks and gets tossed to players on the field. But what happens to the losing team's clothing?

The Philadelphia Eagles' historic first Super Bowl win on February 4 means that boxes of "winning" shirts emblazoned with the New England Patriots' logos are destined for charity. 

Good360, a charitable organization based in Alexandria, Virginia, handles excess consumer merchandise and distributes it to those in need overseas. The losing team's apparel—usually shirts, hats, and sweatshirts—will be held in inventory locations across the U.S. Following the game, Good360 will be informed exactly how much product is available and will then determine where the goods can best be of service.

Good360 chief marketing officer Shari Rudolph tells Mental Floss there's no exact count just yet. But in the past, the merchandise has been plentiful. Based on strong sales after the Chicago Bears’s 2007 NFC Championship win, for example, Sports Authority printed more than 15,000 shirts proclaiming a Bears Super Bowl victory well before the game even started. And then the Colts beat the Bears, 29-17. 

Good360 took over the NFL's excess goods distribution in 2015. For almost two decades prior, an international humanitarian aid group called World Vision collected the unwanted items for MLB and NFL runners-up at its distribution center in Pittsburgh, then shipped them overseas to people living in disaster areas and impoverished nations. After losing Super Bowl XLIII in 2009, Arizona Cardinals gear was sent to children and families in El Salvador. In 2010, after the New Orleans Saints defeated Indianapolis, the Colts gear printed up for Super Bowl XLIV was sent to earthquake-ravaged Haiti.

In 2011, after Pittsburgh lost to the Green Bay Packers, the Steelers Super Bowl apparel went to Zambia, Armenia, Nicaragua, and Romania.

Fans of the Super Bowl team that comes up short can take heart: At least the spoils of losing will go to a worthy cause.

An earlier version of this story appeared in 2009. Additional reporting by Jake Rossen.

All images courtesy of World Vision, unless otherwise noted.

nextArticle.image_alt|e
iStock
arrow
Big Questions
How Are Speed Limits Set?
iStock
iStock

When driving down a road where speed limits are oppressively low, or high enough to let drivers get away with reckless behavior, it's easy to blame the government for getting it wrong. But you and your fellow drivers play a bigger a role in determining speed limits than you might think.

Before cities can come up with speed limit figures, they first need to look at how fast motorists drive down certain roads when there are no limitations. According to The Sacramento Bee, officials conduct speed surveys on two types of roads: arterial roads (typically four-lane highways) and collector streets (two-lane roads connecting residential areas to arterials). Once the data has been collected, they toss out the fastest 15 percent of drivers. The thinking is that this group is probably going faster than what's safe and isn't representative of the average driver. The sweet spot, according to the state, is the 85th percentile: Drivers in this group are thought to occupy the Goldilocks zone of safety and efficiency.

Officials use whatever speed falls in the 85th percentile to set limits for that street, but they do have some wiggle room. If the average speed is 33 mph, for example, they’d normally round up to 35 or down to 30 to reach the nearest 5-mph increment. Whether they decide to make the number higher or lower depends on other information they know about that area. If there’s a risky turn, they might decide to round down and keep drivers on the slow side.

A road’s crash rate also comes into play: If the number of collisions per million miles traveled for that stretch of road is higher than average, officials might lower the speed limit regardless of the 85th percentile rule. Roads that have a history of accidents might also warrant a special signal or sign to reinforce the new speed limit.

For other types of roads, setting speed limits is more of a cut-and-dry process. Streets that run through school zones, business districts, and residential areas are all assigned standard speed limits that are much lower than what drivers might hit if given free rein.

Have you got a Big Question you'd like us to answer? If so, let us know by emailing us at bigquestions@mentalfloss.com.

nextArticle.image_alt|e
iStock
arrow
Big Questions
Do Bacteria Have Bacteria?
iStock
iStock

Drew Smith:

Do bacteria have bacteria? Yes.

We know that bacteria range in size from 0.2 micrometers to nearly one millimeter. That’s more than a thousand-fold difference, easily enough to accommodate a small bacterium inside a larger one.

Nothing forbids bacteria from invading other bacteria, and in biology, that which is not forbidden is inevitable.

We have at least one example: Like many mealybugs, Planococcus citri has a bacterial endosymbiont, in this case the β-proteobacterium Tremblaya princeps. And this endosymbiont in turn has the γ-proteobacterium Moranella endobia living inside it. See for yourself:

Fluorescent In-Situ Hybridization confirming that intrabacterial symbionts reside inside Tremblaya cells in (A) M. hirsutus and (B) P. marginatus mealybugs. Tremblaya cells are in green, and γ-proteobacterial symbionts are in red. (Scale bar: 10 μm.)
Fluorescent In-Situ Hybridization confirming that intrabacterial symbionts reside inside Tremblaya cells in (A) M. hirsutus and (B) P. marginatus mealybugs. Tremblaya cells are in green, and γ-proteobacterial symbionts are in red. (Scale bar: 10 μm.)

I don’t know of examples of free-living bacteria hosting other bacteria within them, but that reflects either my ignorance or the likelihood that we haven’t looked hard enough for them. I’m sure they are out there.

Most (not all) scientists studying the origin of eukaryotic cells believe that they are descended from Archaea.

All scientists accept that the mitochondria which live inside eukaryotic cells are descendants of invasive alpha-proteobacteria. What’s not clear is whether archeal cells became eukaryotic in nature—that is, acquired internal membranes and transport systems—before or after acquiring mitochondria. The two scenarios can be sketched out like this:


The two hypotheses on the origin of eukaryotes:

(A) Archaezoan hypothesis.

(B) Symbiotic hypothesis.

The shapes within the eukaryotic cell denote the nucleus, the endomembrane system, and the cytoskeleton. The irregular gray shape denotes a putative wall-less archaeon that could have been the host of the alpha-proteobacterial endosymbiont, whereas the oblong red shape denotes a typical archaeon with a cell wall. A: archaea; B: bacteria; E: eukaryote; LUCA: last universal common ancestor of cellular life forms; LECA: last eukaryotic common ancestor; E-arch: putative archaezoan (primitive amitochondrial eukaryote); E-mit: primitive mitochondrial eukaryote; alpha:alpha-proteobacterium, ancestor of the mitochondrion.

The Archaezoan hypothesis has been given a bit of a boost by the discovery of Lokiarcheota. This complex Archaean has genes for phagocytosis, intracellular membrane formation and intracellular transport and signaling—hallmark activities of eukaryotic cells. The Lokiarcheotan genes are clearly related to eukaryotic genes, indicating a common origin.

Bacteria-within-bacteria is not only not a crazy idea, it probably accounts for the origin of Eucarya, and thus our own species.

We don’t know how common this arrangement is—we mostly study bacteria these days by sequencing their DNA. This is great for detecting uncultivatable species (which are 99 percent of them), but doesn’t tell us whether they are free-living or are some kind of symbiont. For that, someone would have to spend a lot of time prepping environmental samples for close examination by microscopic methods, a tedious project indeed. But one well worth doing, as it may shed more light on the history of life—which is often a history of conflict turned to cooperation. That’s a story which never gets old or stale.

This post originally appeared on Quora. Click here to view.

SECTIONS

arrow
LIVE SMARTER